Sodium-induced conformation changes in membrane transport proteins

Neurochemistry of L-Glutamate Transport in the CNS: A Review of Thirty Years of Progress

The review highlights the landmark studies leading from the discovery and initial characterization of the Na+-dependent "high affinity" uptake in the mammalian brain to the cloning of individual transporters and the subsequent expansion of the field into the realm of molecular biology. When the data and hypotheses from 1970's are confronted with the recent developments in the field, we can conclude that the suggestions made nearly thirty years ago were essentially correct: the uptake, mediated by an active transport into neurons and glial cells, serves to control the extracellular concentrations of L-glutamate and prevents the neurotoxicity. The modern techniques of molecular biology may have provided additional data on the nature and location of the transporters but the classical neurochemical approach, using structural analogues of glutamate designed as specific inhibitors or substrates for glutamate transport, has been crucial for the investigations of particular roles that glutamate transport might play in health and disease. Analysis of recent structure/activity data presented in this review has yielded a novel insight into the pharmacological characteristics of L-glutamate transport, suggesting existence of additional heterogeneity in the system, beyond that so far discovered by molecular genetics. More compounds that specifically interact with individual glutamate transporters are urgently needed for more detailed investigations of neurochemical characteristics of glutamatergic transport and its integration into the glutamatergic synapses in the central nervous system. A review with 162 references.

Quantitative autoradiography of Na+-dependent [3H]L-aspartate binding to L-glutamate transporters in rat brain: structure-activity studies using L-trans-pyrrolidine-2,4-dicarboxylate (L-t-PDC) and 2-(carboxycyclopropyl)-glycine (CCG)

Sodium-dependent binding of [3H]L-aspartate was studied in thaw-mounted horizontal sections of fresh-frozen (i.e. not fixed) rat brain. After the incubation with [3H]L-aspartate, the sections were exposed against a 3H-sensitive film and the resulting autoradiograms were evaluated by quantitative densitometry. Effects of several inhibitors were examined and their potency expressed as IC50 and nH. Together with previously published data, the present study supports the view that [3H]L-aspartate binding to fresh-frozen sections of rat brain represents interaction of the radioligand with the substrate-binding sites on glutamate transporters. The most potent inhibitors were (2S,3S,4R)-2-(carboxycyclopropyl)-glycine (L-CCG III) and (2S,4R)-4-methylglutamate. In contrast, L-anti,endo-3,4-methanopyrrolidine dicarboxylate (L-a,e-MPDC) was about an order of magnitude less potent. Only subtle regional variations in the characteristics of inhibitors of [3H]L-aspartate binding were detected. It is not certain whether these differences reflect regional variations in the distribution of individual glutamate transporters or regional peculiarities in their pharmacological characteristics. In particular, (2S,4R)-4-methylglutamate, shown previously to differentiate between GLT-1 (principal glutamate transporter in the forebrain) and GLAST (expressed mainly in the cerebellum), did not strongly differentiate between the binding of [3H]L-aspartate in forebrain and cerebellum. Computer-assisted molecular modelling using selected glutamate analogues with restricted conformation (L-trans-pyrrolidine-2,4-dicarboxylate and four isomers of 2-(carboxycyclopropyl)-glycine: L- and D-CCG I, L-CCG III and L-CCG IV) identified at least one area of unfavourable steric interaction. We conclude that the quantitative autoradiographic studies using [3H]L-aspartate or other transporter-specific ligands, will be a useful tool to study the pharmacology of substrate binding sites on glutamate transporters in the mammalian brain in situ.

Molecular mechanisms of tissue determination and pattern formation in amphibian embryos

Factors of the TGF-beta superfamily (activin, vegetalizing factor) and the FGF family determine endoderm and mesoderm. The dorsoventral polarity of the mesoderm depends on additional factors (BMP-4, Wnt-8, noggin). Activin can directly activate gene transcription by signal transduction. Mesoderm is determined by factors prelocalized in the marginal zone. Its differentiation depends also on the animal ectoderm. Neural inducing factors have been partially purified. A masked neuralizing factor in the ectoderm is activated by induction of the ectoderm to the nervous system. Phorbolester can evoke neuralization signaling.

Characterization of the nipecotic binding to rat brain membranes

1. The specific binding of [3H]Nip and [3H]GABA to rat brain membranes has been reexamined. 2. Specific binding of [3H]Nip and [3H]GABA was exclusively dependent on sodium ions in a cooperative manner (Hill coefficient 2.2 +/- 0.2 and 2.4 +/- 0.3 for [3H]Nip and [3H]GABA binding, respectively). Potassium, lithium or choline chloride salts were ineffective for replacing NaCl. 3. Maximal binding was observed at 2 degrees C. The association constants were K+1 = 0.033 min-1 microM-1 for [3H]GABA. The dissociation constants obtained by the addition of 1 mM of non-labeled GABA were 0.087 +/- 0.01 min-1 and 0.139 +/- 0.025 min-1 for [3H]Nip and [3H]GABA, respectively. Scatchard curves were in agreement with these constants, KD = 1.6 microM for [3H]GABA and 2.6 microM for [3H]Nip with equal Bmax = 138 pmol per mg protein. 4. The dissociation constants for [3H]Nip bound increased from 0 to 0.035, 0.18 and 0.58 min-1 at 2, 16, 26 and 37 degrees C, respectively, contrary to the hydrophobic derivate of nipecotic acid, NO 328. 5. Pharmacological characterization and regional brain distribution of [3H]Nip and [3H]GABA binding and uptake, suggest that [3H]Nip specifically labels the neuronal GABA uptake system, absent in peripheral tissues.

Sensitivity of system A and ASC transport activities to thiol-group-modifying reagents in rat liver plasma-membrane vesicles. Evidence for a direct binding of N-ethylmaleimide and iodoacetamide on A and ASC carriers

1. In the present study we have examined the sensitivity of A and ASC amino-acid-carrier activities in rat liver plasma-membrane vesicles to the thiol-group modifying reagents N-ethylmaleimide (NEM) and iodoacetamide (IA). To this end, the different Na(+)-dependent entities involved in alanine transport were assessed. 2. NEM inactivated Na(+)-dependent alanine transport as a result of the inhibition of both system A and ASC transport activities. The functional sensitivity of system A to NEM was greater than that of system ASC. 3. The presence of L-alanine (10 mM) during the exposure of vesicles to NEM afforded partial protection to system A, but not to the ASC, carrier. This effect was specific, since the presence of L-phenylalanine (10 mM) did not cause any protection. 4. Na+ did not protect A or ASC carriers against NEM inactivation; however, the presence of Na+ (100 mM-NaCl) and L-alanine (10 mM) during the exposure of the vesicles to NEM protected against inactivation of system A and ASC transport activities. The extent of protection was greater in the case of the system ASC transport activity than in the case of the A carrier. 5. IA also diminished Na(+)-dependent alanine transport by inhibition of A and ASC transport activities. Sodium and L-alanine afforded protection to both A and ASC transport activities from the inhibitory action of IA. The extent of protection induced by substrates was similar for both carriers. 6. It is concluded that there is one, or several, free thiol groups in A and ASC carriers, the integrity of which is essential for transport activity. Sensitivity to thiol-group-specific reagents and the pattern of protection with substrates against inactivation is different in A and ASC carriers. That suggests the existence of topological dissimilarities regarding the thiol-group containing site(s) in A and ASC amino acid carriers.

Sodium ions protect a membrane transport protein from proteolysis

Na+-dependent alanine transport activity in vesicles prepared from pigeon erythrocyte membranes was examined after exposure of the vesicles to some proteinases under various conditions. The presence of sodium ions during proteolysis affords considerable protection of alanine transport activity from the inhibitory action of the proteinases. The concentration of sodium ions required for half-maximum protection is greater than that needed for half-maximum activation of alanine uptake. The site of protective action could be at either or both surfaces of the membrane because the vesicles are very permeable to sodium ions. Neither measurement of residual protein content nor analysis by polyacrylamide gel electrophoresis revealed any differences in the extent of protein degradation occurring in the presence and absence of sodium ions, suggesting that the transporter constitutes only a minor membrane component. We conclude that sodium ions probably induce a conformation change in the transporter.

Differentiation of the Ca2+-stimulated binding from the Cl- -dependent binding of [3H]glutamate in synaptic membranes from rat brain

The effect of Ca2+ as well as Cl- ions on [3H]glutamate (Glu) binding was re-examined using rat brain synaptic membranes frozen at -80 degrees C in 0.32 M sucrose. The inclusion of 20 mM ammonium chloride or 20 mM ammonium chloride plus 2.5 mM calcium acetate disclosed the Cl- -dependent binding or Ca2+-stimulated binding even at 2 min after the initiation of incubation at 30 degrees C and each binding reached a plateau within 30 min. In contrast, the binding reached its maximal value within 10 min followed by a progressive decline up to 60 min in the presence of 100 mM sodium acetate. Scatchard analysis revealed that Cl- as well as Cl-/Ca2+ ions invariably caused a significant increment of the number of binding sites without altering their affinity, whereas Na+ ions induced a prominent increment of the density of binding sites with a concomitant lowering of their affinity. DL-2-Amino-4-phosphonobutyric acid selectively abolished the Cl- -dependent and Ca2+-stimulated bindings without significantly affecting the basal or Na+-dependent binding. Quisqualic acid induced a profound inhibition of both Cl- -dependent and Ca2+-stimulated bindings, to a significantly greater extent than that of the basal and Na+-dependent bindings. D-Aspartic acid exhibited a potent inhibition of the Na+-dependent binding with a significantly less potent displacement of the basal, Cl- -dependent and Ca2+-stimulated bindings. An inhibitor of anion transport, 4,4'-diisothiocyanatostilbene-2,2'-disulfonic acid (DIDS), not only eliminated the Cl- -dependent binding, but also completely abolished the Ca2+-stimulated binding. Scatchard analysis revealed that DIDS (0.1 mM) prevented the Cl- - and Cl-/Ca2+-induced increment of the density of binding sites with no significant change of their affinity. Pretreatment of the membranes with hydrophilic SH-reactive agents such as N-ethylmaleimide and 5,5'-dithiobis-(2-nitrobenzoic acid) invariably resulted in a more sensitive inhibition of the Ca2+-stimulated binding than that of the Cl- -dependent binding, while hydrophobic reagent p-chloromercuribenzoic acid produced a similarly potent elimination of the Cl- -dependent and Ca2+-stimulated bindings. Calcium-stimulated binding was also found to be sensitively diminished by dithiothreitol and dithioerythritol as compared with the Cl- -dependent binding. In vitro addition of L-ascorbic acid (10(-6)-10(-3) M) attenuated the Ca2+-stimulated binding to a significantly greater extent than the inhibition of the Cl- -dependent binding.(ABSTRACT TRUNCATED AT 400 WORDS)

Characterization of Na+-dependent binding sites of [3H]glutamate in synaptic membranes from rat brain

Some biochemical characteristics of Na+-dependent binding of [3H]L-glutamic acid (Glu) were studied using crude synaptic membrane preparations from the rat brain as compared with Na+-independent binding. In vitro addition of sodium chloride (1-100 mM) exhibited a significant enhancement of [3H]Glu binding to synaptic membranes in a concentration-dependent manner independent of the incubation temperature employed (2 or 30 degrees C). In contrast, sodium acetate elicited a concentration-dependent augmentation of the binding at 2 degrees C to a significantly greater extent than that found at 30 degrees C. It was found that the binding found in the presence of 100 mM sodium acetate reached its maximal value within 10 min of incubation followed by a rapid decline up to 60 min at 30 degrees C, while gradually increasing up to 60 min at 2 degrees C. The Na+-independent basal binding was significantly activated by the alteration of incubation temperature from 2 to 30 degrees C and reached equilibrium within 10 min of incubation at both incubation temperatures. The Na+-dependent binding was more promptly attenuated by the addition of excess of non-radioactive Glu (1 mM) at 30 degrees C than that at 2 degrees C, whereas the Na+-independent binding was greatly suppressed by the addition at 2 degrees C in comparison with that at 30 degrees C. Quisqualic acid induced a considerably less-potent inhibition of the Na+-dependent binding than that of the Na+-independent binding. Neither N-methyl-D-aspartic acid nor kainic acid had such a significant effect on each binding.(ABSTRACT TRUNCATED AT 250 WORDS)

Regulatory and energetic role of Na+ in amino acid uptake by fertilized sea urchin eggs

Relationships between the Na+ dependent amino acid uptake displayed by fertilized sea urchin eggs and the electrochemical gradient of Na+ was investigated. The time course of Na+ content and valine or alanine uptake was simultaneously monitored in Na+ loaded eggs [by fertilization in K+-free artificial sea water (OK-ASW), or by using monensin, antimycin, cyanide, or ciguatoxin]. Our results demonstrate that the uphill amino acid uptake follows the "Na+ gradient hypothesis." Subsequent fertilization of eggs Na+ depleted by ammonia for 40 min stimulates to a great extent the development of amino acid uptake as compared with controls eggs. By using simultaneous change of external and intracellular Na+ concentration, we studied the specific role of this ion. An increase in internal Na+ inhibits the uptake through trans inhibitory action while an increase in external Na+ stimulates the efficiency of the uptake system. In eggs fertilized since 30 min, hyperpolarization obtained in K+-free ASW stimulates amino acid uptake while depolarization (transfer from K+ free ASW to ASW) inhibits it. This potential-dependent effect developed after fertilization with a time course similar to that the establishment of K+ conductance described by R. A. Steinhardt, L. Lundin, and D. Mazia (1971, Proc. Natl. Acad. Sci. USA 68, 2426-2430). In conclusion, our results point out that slight modulations in the activity of the Na+ pump can widely affect the amino acid uptake, suggesting that activation of Na+/K+ ATPase has a key role in the stimulation of amino acid transport.