Amphipols from A to Z.

Amphipols (APols) are short amphipathic polymers that can substitute for detergents to keep integral membrane proteins (MPs) water soluble. In this review, we discuss their structure and solution behavior; the way they associate with MPs; and the structure, dynamics, and solution properties of the resulting complexes. All MPs tested to date form water-soluble complexes with APols, and their biochemical stability is in general greatly improved compared with MPs in detergent solutions. The functionality and ligand-binding properties of APol-trapped MPs are reviewed, and the mechanisms by which APols stabilize MPs are discussed. Applications of APols include MP folding and cell-free synthesis, structural studies by NMR, electron microscopy and X-ray diffraction, APol-mediated immobilization of MPs onto solid supports, proteomics, delivery of MPs to preexisting membranes, and vaccine formulation.

Phosphorylated Ca2+-ATPase stable enough for structural studies.

The atomic structure of sarcoplasmic reticulum Ca(2+)-ATPase, in a Ca(2+)-bound conformation, has recently been elucidated (Toyoshima, C., Nakasako, M., Nomura, H. & Ogawa, H. (2000) Nature 405, 647-655). Important steps for further understanding the mechanism of ion pumps will be the atomic structural characterization of different key conformational intermediates of the transport cycle, including phosphorylated intermediates. Following our previous report (Champeil, P., Henao, F., Lacapère, J.-J. & McIntosh, D. B. (2000) J. Biol. Chem. 276, 5795-5803), we show here that it is possible to prepare a phosphorylated form of sarcoplasmic reticulum Ca(2+)-ATPase (labeled with fluorescein isothiocyanate) with a week-long stability both in membranes and in mixed lipid-detergent micelles. We show that this phosphorylated fluorescein isothiocyanate-ATPase can form two-dimensional arrays in membranes, similar to those that were used previously to reconstruct from cryoelectron microscopy images the three-dimensional structure of Ca(2+)-free unphosphorylated ATPase. The results also provide hope that crystals of phosphorylated Ca(2+)-ATPase suitable for x-ray crystallography will be achieved.

A remarkably stable phosphorylated form of Ca2+-ATPase prepared from Ca2+-loaded and fluorescein isothiocyanate-labeled sarcoplasmic reticulum vesicles.

After the nucleotide binding domain in sarcoplasmic reticulum Ca2+-ATPase has been derivatized with fluorescein isothiocyanate at Lys-515, ATPase phosphorylation in the presence of a calcium gradient, with Ca2+ on the lumenal side but without Ca2+ on the cytosolic side, results in the formation of a species that exhibits exceptionally low probe fluorescence (Pick, U. (1981) FEBS Lett. 123, 131-136). We show here that, as long as the free calcium concentration on the cytosolic side is kept in the nanomolar range, this low fluorescence species is remarkably stable, even when the calcium gradient is subsequently dissipated by ionophore. This species is a Ca2+-free phosphorylated species. The kinetics of Ca2+ binding to it indicates that its transport sites are exposed to the cytosolic side of the membrane and retain a high affinity for Ca2+. Thus, in the ATPase catalytic cycle, an intrinsically transient phosphorylated species with transport sites occupied but not yet occluded must also have been stabilized by fluorescein isothiocyanate (FITC), possibly mimicking ADP. The low fluorescence mainly results from a change in FITC absorption. The Ca2+-free low fluorescence FITC-ATPase species remains stable after addition of thapsigargin in the absence or presence of decavanadate, or after solubilization with dodecylmaltoside. The remarkable stability of this phosphoenzyme species and the changes in FITC spectroscopic properties are discussed in terms of a putative FITC-mediated link between the nucleotide binding domain and the phosphorylation domain in Ca2+-ATPase, and the possible formation of a transition state-like conformation with a compact cytosolic head. These findings might open a path toward structural characterization of a stable phosphorylated form of Ca2+-ATPase for the first time, and thus to further insights into the pump's mechanism.

Interaction of membrane proteins and lipids with solubilizing detergents.

Detergents are indispensable in the isolation of integral membrane proteins from biological membranes to study their intrinsic structural and functional properties. Solubilization involves a number of intermediary states that can be studied by a variety of physicochemical and kinetic methods; it usually starts by destabilization of the lipid component of the membranes, a process that is accompanied by a transition of detergent binding by the membrane from a noncooperative to a cooperative interaction already below the critical micellar concentration (CMC). This leads to the formation of membrane fragments of proteins and lipids with detergent-shielded edges. In the final stage of solubilization membrane proteins are present as protomers, with the membrane inserted sectors covered by detergent. We consider in detail the nature of this interaction and conclude that in general binding as a monolayer ring, rather than as a micelle, is the most probable mechanism. This mode of interaction is supported by neutron diffraction investigations on the disposition of detergent in 3-D crystals of membrane proteins. Finally, we briefly discuss the use of techniques such as analytical ultracentrifugation, size exclusion chromatography, and mass spectrometry relevant for the structural investigation of detergent solubilized membrane proteins.

Interaction of amphipols with sarcoplasmic reticulum Ca2+-ATPase.

Amphipols are short-chain amphipathic polymers designed to keep membrane proteins soluble in aqueous solutions. We have evaluated the effects of the interaction of amphipols with sarcoplasmic reticulum Ca(2+)-ATPase either in a membrane-bound or a soluble form. If the addition of amphipols to detergent-solubilized ATPase was followed by removal of detergent, soluble complexes formed, but these complexes retained poor ATPase activity, were not very stable upon long incubation periods, and at high concentrations they experienced aggregation. Nevertheless, adding excess detergent to diluted detergent-free ATPase-amphipol complexes incubated for short periods immediately restored full activity to these complexes, showing that amphipols had protected solubilized ATPase from the rapid and irreversible inactivation that otherwise follows detergent removal. Amphipols also protected solubilized ATPase from the rapid and irreversible inactivation observed in detergent solutions if the ATPase Ca(2+) binding sites remain vacant. Moreover, in the presence of Ca(2+), amphipol/detergent mixtures stabilized concentrated ATPase against inactivation and aggregation, whether in the presence or absence of lipids, for much longer periods of time (days) than detergent alone. Our observations suggest that mixtures of amphipols and detergents are promising media for handling solubilized Ca(2+)-ATPase under conditions that would otherwise lead to its irreversible denaturation and/or aggregation.

Tryptophan octyl ester in detergent micelles of dodecylmaltoside: fluorescence properties and quenching by brominated detergent analogs.

The fluorescence properties of tryptophan octyl ester (TOE), a hydrophobic model of Trp in proteins, were investigated in various mixed micelles of dodecylmaltoside (DM) and 7,8-dibromododecyl beta-maltoside (BrDM) or 10,11-dibromoundecanoyl beta-maltoside (BrUM). This study focuses on the mechanism via which these brominated detergents quench the fluorescence of TOE in a micellar system. The experiments were performed at a pH at which TOE is uncharged and almost completely bound to detergent micelles. TOE binding was monitored by its enhanced fluorescence in pure DM micelles or its quenched fluorescence in pure BrUM or BrDM micelles. In DM/BrUM and DM/BrDM mixed micelles, the fluorescence intensity of TOE decreased, as a nonlinear function of the molar fraction of brominated detergent, to almost zero in pure brominated detergent. The indole moiety of TOE is therefore highly accessible to the bromine atoms located on the detergent alkyl chain because quenching by bromines occurs by direct contact with the fluorophore. TOE is simultaneously poorly accessible to iodide (I(-)), a water-soluble collisional quencher. TOE time-resolved fluorescence intensity decay is heterogeneous in pure DM micelles, with four lifetimes (from 0.2 to 4.4 ns) at the maximum emission wavelength. Such heterogeneity may arise from dipolar relaxation processes in a motionally restricted medium, as suggested by the time-dependent (nanoseconds) red shift (11 nm) of the TOE emission spectrum, and from the existence of various TOE conformations. Time-resolved quenching experiments for TOE in mixed micelles showed that the excited-state lifetime values decreased only slightly with increases in the proportion of BrDM or BrUM. In contrast, the relative amplitude of the component with the longest lifetime decreased significantly relative to that of the short-lived species. This is consistent with a mainly static mechanism for the quenching of TOE by brominated detergents. Molecular modeling of TOE (in vacuum and in water) suggested that the indole ring was stabilized by folding back upon the octyl chain, forming a hairpin conformation. Within micelles, the presence of such folded conformations, making it possible for the entire molecule to be located in the hydrophobic part of the micelle, is consistent with the results of fluorescence quenching experiments. TOE rotational correlation time values, in the nanosecond range, were consistent with a hindered rotation of the indole moiety and a rotation of the complete TOE molecule in the pure DM or mixed detergent micelles. These results, obtained with a simple micellar model system, provide a basis for the interpretation of fluorescence quenching by brominated detergents in more complex systems such as protein- or peptide-detergent complexes.

From calcium blips to calcium puffs: theoretical analysis of the requirements for interchannel communication.

In the cytoplasm of cells of different types, discrete clusters of inositol 1,4,5-trisphosphate-sensitive Ca(2+) channels generate Ca(2+) signals of graded size, ranging from blips, which involve the opening of only one channel, to moderately larger puffs, which result from the concerted opening of a few channels in the same cluster. These channel clusters are of unknown size or geometrical characteristics. The aim of this study was to estimate the number of channels and the interchannel distance within such a cluster. Because these characteristics are not attainable experimentally, we performed computer stochastic simulations of Ca(2+) release events. We conclude that, to ensure efficient interchannel communication, as experimentally observed, a typical cluster should contain two or three tens of inositol 1,4,5-trisphosphate-sensitive Ca(2+) channels in close contact.

Ligand binding to macromolecules or micelles: use of centrifugal ultrafiltration to measure low-affinity binding.

We describe a method for estimating ligand binding to a macromolecular sample under conditions where this binding is of low affinity and must be measured under equilibrium conditions, without removal of the unbound ligand. The method is based on centrifugal ultrafiltration through a membrane with a molecular mass cut-off intermediate between that of the ligand and that of the target, and the amount of bound ligand is calculated from the difference between the (total) ligand in the concentrated sample and the (free) ligand in the ultrafiltrate. Centrifugal ultrafiltration makes it possible to separate free ligand from bound ligand (without changing its concentration) and to simultaneously concentrate the target (such that the proportion of bound ligand becomes significant, even under low-affinity binding conditions). We applied this technique, using Centricon 10 (Amicon) devices, to several cases (soluble proteins, intact membranes, detergent-solubilized proteins, and pure detergent micelles) and assessed its value with respect to the common artifacts that occur in other protocols involving protein retention on nitrocellulose filters (nonspecific ligand adsorption and protein denaturation).

The cytoplasmic loop located between transmembrane segments 6 and 7 controls activation by Ca2+ of sarcoplasmic reticulum Ca2+-ATPase.

During active cation transport, sarcoplasmic reticulum Ca2+-ATPase, like other P-type ATPases, undergoes major conformational changes, some of which are dependent on Ca2+ binding to high affinity transport sites. We here report that, in addition to previously described residues of the transmembrane region (Clarke, D. M., Loo, T. W., Inesi, G., and MacLennan, D. H. (1989) Nature 339, 476-478), the region located in the cytosolic L6-7 loop connecting transmembrane segments M6 and M7 has a definite influence on the sensitivity of the Ca2+-ATPase to Ca2+, i.e. on the affinity of the ATPase for Ca2+. Cluster mutation of aspartic residues in this loop results in a strong reduction of the affinity for Ca2+, as shown by the Ca2+ dependence of ATPase phosphorylation from either ATP or Pi. The reduction in Ca2+ affinity for phosphorylation from Pi is observed both at acidic and neutral pH, suggesting that these mutations interfere with binding of the first Ca2+, as proposed for some of the intramembranous residues essential for Ca2+ binding (Andersen, J. P. (1995) Biosci. Rep. 15, 243-261). Treatment of the mutated Ca2+-ATPase with proteinase K, in the absence or presence of various Ca2+ concentrations, leads to Ca2+-dependent changes in the proteolytic degradation pattern similar to those in the wild type but observed only at higher Ca2+ concentrations. This implies that these effects are not due to changes in the conformational state of Ca2+-free ATPase but that changes affecting the proteolytic digestion pattern require higher Ca2+ concentrations. We conclude that aspartic residues in the L6-7 loop might interact with Ca2+ during the initial steps of Ca2+ binding.

Stochastic simulation of a single inositol 1,4,5-trisphosphate-sensitive Ca2+ channel reveals repetitive openings during 'blip-like' Ca2+ transients.

Confocal microscope studies with fluorescent dyes of inositol 1,4,5-trisphosphate (InsP3)-induced intracellular Ca2+ mobilization recently established the existence of 'elementary' events, dependent on the activity of individual InsP3-sensitive Ca2+ channels. In the present work, we try by theoretical stochastic simulation to explain the smallest signals observed in those studies, which were referred to as Ca2+ 'blips' [Parker I., Yao Y. Ca2+ transients associated with openings of inositol trisphosphate-gated channels in Xenopus oocytes. J Physiol Lond 1996; 491: 663-668]. For this purpose, we assumed a simple molecular model for the InsP3-sensitive Ca2+ channel and defined a set of parameter values accounting for the results obtained in electrophysiological bilayer experiments [Bezprozvanny I., Watras J., Ehrlich B.E. Bell-shaped calcium-response curves of Ins(1,4,5)P3- and calcium-gated channels from endoplasmic reticulum of cerebellum. Nature 1991; 351: 751-754; Bezprozvanny I., Ehrlich B.E. Inositol (1,4,5)-trisphosphate (InsP3)-gated Ca channels from cerebellum: conduction properties for divalent cations and regulation by intraluminal calcium. J Gen Physiol 1994; 104: 821-856]. With a stochastic procedure which considered cytosolic Ca2+ diffusion explicitly, we then simulated the behaviour of a single channel, placed in a realistic physiological environment. An attractive result was that the simulated channel exhibited bursts of activity, arising from repetitive channel openings, which were responsible for transient rises in Ca2+ concentration and were reminiscent of the relatively long-duration experimental Ca2+ blips. The influence of the values chosen for the various parameters (affinity and diffusion coefficient of the buffers, luminal Ca2+ concentration) on the kinetic characteristics of these theoretical blips is analyzed.

Characterization of a protease-resistant domain of the cytosolic portion of sarcoplasmic reticulum Ca2+-ATPase. Nucleotide- and metal-binding sites.

Treatment of rabbit sarcoplasmic reticulum Ca2+-ATPase with a variety of proteases, including elastase, proteinase K, and endoproteinases Asp-N and Glu-C, results in accumulation of soluble fragments starting close to the ATPase phosphorylation site Asp351 and ending in the Lys605-Arg615 region, well before the conserved sequences generally described as constituting the "hinge" region of this P-type ATPase (residues 670-760). These fragments, designated as p29/30, presumably originate from a relatively compact domain of the cytoplasmic head of the ATPase. They retain two structural characteristics of intact Ca2+-ATPase as follows: high sensitivity of peptidic bond Arg505-Ala506 to trypsin cleavage, and high reactivity of lysine residue Lys515 toward the fluorescent label fluorescein 5'-isothiocyanate. Regarding functional properties, these fragments retain the ability to bind nucleotides, although with reduced affinity compared with intact Ca2+-ATPase. The fragments also bind Nd3+ ions, leaving open the possibility that these fragments could contain the metal-binding site(s) responsible for the inhibitory effect of lanthanide ions on ATPase activity. The p29/30 soluble domain, like similar proteolytic fragments that can be obtained from other P-type ATPases, may be useful for obtaining three-dimensional structural information on the cytosolic portion of these ATPases, with or without bound nucleotides. From our findings we infer that a real hinge region with conformational flexibility is located at the C-terminal boundary of p29/30 (rather than in the conserved region of residues 670-760); we also propose that the ATP-binding cleft is mainly located within the p29/30 domain, with the phosphorylation site strategically located at the N-terminal border of this domain.

Dissociation of Ca2+ from sarcoplasmic reticulum Ca2+-ATPase and changes in fluorescence of optically selected Trp residues. Effects of KCl and NaCl and implications for substeps in Ca2+ dissociation.

Sequential dissociation of the two Ca2+ ions bound to non-phosphorylated sarcoplasmic reticulum Ca2+-ATPase was triggered by addition, in a stopped-flow experiment, of quin2, which acted both as a high-affinity chelator and as a Ca2+-sensitive fluorescent probe. The kinetics of Ca2+ dissociation were deduced from the observed changes in quin2 fluorescence in the visible region (with lambdaex = 313 nm), while fluorescence detection in the UV region (with lambdaex = 290 nm) made it possible to monitor the tryptophan fluorescence changes accompanying this dissociation under the same ionic conditions. In the absence of KCl or NaCl, at pH 6 or 7, the observed changes in quin2 fluorescence were monoexponential, with rate constants very close to those of the changes in ATPase tryptophan fluorescence, which also appeared monophasic. In the presence of 100 mM KCl, quin2 fluorescence changes, although still monoexponential, were faster than in the absence of the monovalent ions but distinctly slower than the changes in tryptophan fluorescence, which were accelerated to a larger extent. In addition, the apparent kinetics of the Trp fluorescence changes depended on the excitation wavelength. Using an excitation wavelength of 296 nm, the Trp fluorescence drop was still faster than with an excitation wavelength of 290 nm, and in the presence of NaCl it even displayed a clear undershoot. We conclude that in the presence of KCl or NaCl and with an excitation wavelength of 290 nm, the rapid drop in tryptophan fluorescence mainly monitors the dissociation of the first of the two Ca2+ ions to be released from Ca2+-ATPase, while excitation at 296 nm optically selects a subpopulation of Trp residues whose fluorescence level is lower in the ATPase species with one Ca2+ ion bound than in the Ca2+-deprived ATPase species. The latter conditions result in an initial drop in Trp fluorescence whose apparent rate constant (in single-exponential analysis) is faster than the true rate of dissociation of the first Ca2+ ion and in a subsequent slower rise related to dissociation of the second Ca2+ ion. The difference between results obtained in the absence and in the presence of K+ or Na+ is due to an antagonizing effect of these cations on proton-induced conformational rearrangement of Ca2+-free ATPase, a conformational rearrangement which changes the ATPase Trp fluorescence level and significantly affects the cooperativity of Ca2+ binding at equilibrium.

The cytoplasmic loop between putative transmembrane segments 6 and 7 in sarcoplasmic reticulum Ca2+-ATPase binds Ca2+ and is functionally important.

Limited proteolysis by proteinase K of rabbit SERCA1 Ca2+-ATPase generates a number of fragments which have been identified recently. Here, we have focused on two proteolytic C-terminal fragments, p20C and p19C, starting at Gly-808 and Asp-818, respectively. The longer peptide p20C binds Ca2+, as deduced from changes in migration rate by SDS-polyacrylamide gel electrophoresis performed in the presence of Ca2+ as well as from labeling with 45Ca2+ in overlay experiments. In contrast, the shorter peptide p19C, a proteolysis fragment identical to p20C but for 10 amino acids missing at the N-terminal side, did not bind Ca2+ when submitted to the same experiments. Two cluster mutants of Ca2+-ATPase, D813A/D818A and D813A/D815A/D818A, expressed in the yeast Saccharomyces cerevisiae, were found to have a very low Ca2+-ATPase activity. Region 808-818 is thus essential for both Ca2+ binding and enzyme activity, in agreement with similar results recently reported for the homologous gastric H+, K+-ATPase (Swarts, H. G. P., Klaassen, C. H. W., de Boer, M., Fransen, J. A. M. , and De Pont, J. J. H. H. M. (1996) J. Biol. Chem. 271, 29764-29772). However, the accessibility of proteinase K to the peptidyl link between Leu-807 and Gly-808 clearly shows that the transmembrane segment M6 ends before region 808-818. It is remarkable that critical residues for enzyme activity are located in a cytoplasmic loop starting at Gly-808.

Brominated detergents as tools to study protein-detergent interactions.

In order to study protein-detergent short-range interactions, we analyzed the quenching by brominated detergents of reticulum sarcoplasmic (SR) Ca(2+)-ATPase intrinsic fluorescence. For this purpose, 7,8-dibromododecyl beta-maltoside and 2-O-(10,11-dibromoundecanoyl)sucrose, brominated analogs of two non-ionic detergents, the frequently used dodecylmaltoside and the newly synthesized 2-O-lauroylsucrose respectively, were prepared. Rayleigh scattering measurements showed that the brominated detergents efficiently and rapidly solubilized SR vesicles like their non-brominated analogs although at slightly higher concentrations. Similarly, each analog had a slightly higher critical micellar concentration than its parent detergent. The partition coefficient K (expressed as the ratio of the molar fraction of detergent in the SR lipid phase to that in the aqueous phase, at pH 7.5 and 20 degrees C) was similar for brominated and non-brominated dodecyl maltoside (3.5-4 x 10(5)) and slightly lower for dibromoundecanoylsucrose (approximately 10(5)) than for lauroylsucrose (approximately 2 x 10(5)). At detergent concentrations too low to solubilize the membrane, the brominated detergents rapidly inserted (within seconds) into SR vesicles. In this concentration range, Ca(2+)-ATPase fluorescence quenching steadily increased with detergent concentration. When the membrane was saturated with detergent, the residual fluorescence was about half of its initial value, indicating significant protein-detergent, contacts, possibly due to a slightly higher affinity of Ca(2+)-ATPase for these detergents than for phospholipids. For higher detergent concentrations, solubilizing the membrane, the fluorescence continued to decrease with detergent concentration, with no evidence for a dramatic change in the average hydrophobic environment of the protein during the transition from bilayers to a soluble state. For still higher detergent concentrations, above that necessary for membrane solubilization, the fluorescence was further quenched to a residual relative value of about 20%, corresponding to further delipidation of the protein surface, in agreement with previous results [de Foresta, B., le Maire, M., Orlowski, S., Champeil, P., Lund, S., Møller, J.V., Michelangeli, F. & Lee, A.G. (1989) Biochemistry 28, 2558-2567]. Fluorescence quenching for solubilized Ca(2+)-ATPase was quickly reversed upon addition of excess non-brominated detergent. The effects of the four detergents on the Ca(2+)-ATPase hydrolysis of p-nitrophenyl phosphate were similar and correlated with the protein-detergent contacts evidenced above. In conclusion, both these brominated detergents appear to be promising tools to study protein-detergent interactions at the hydrophobic surface of a membrane protein, either in a membrane or in solubilized complexes.

Characterization of the co-agonist effects of strontium and calcium on myo-inositol trisphosphate-dependent ion fluxes in cerebellar microsomes.

Using sheep cerebellum microsomes previously loaded with 45Ca2+ or 90Sr2+, we measured the dependence of inositol 1,4,5-trisphosphate (InsP3)-induced efflux of these ions on Ca2+ or Sr2+ on the cytosolic side. At a low InsP3 concentration, Ca2+ in the submicromolar range only poorly activated 45Ca2+ or 90Sr2+ efflux, and higher Ca2+ concentrations were inhibitory. In contrast, Sr2+ in the micromolar range activated release efficiently, while only very high Sr2+ concentrations were inhibitory. Experiments were repeated in the presence of a high InsP3 concentration, which allowed increasing free Ca2+ to micromolar concentrations without inducing complete inhibition of the InsP3-dependent efflux. Under these conditions, micromolar Ca2+ was found to activate efflux to a large extent, similar to that previously found with Sr2+. Optimal activation by Ca2+ of the InsP3-dependent channel occurs at micromolar rather than submicromolar free Ca2+ concentrations, but at too low an InsP3 concentration, Ca(2+)-induced activation is counteracted by Ca(2+)-induced inactivation. Separate measurements of [3H]-InsP3 binding at a low concentration showed that Sr2+ and Ca2+ did not enhance the amount of bound [3H]-InsP3, implying that the activating effect of Sr2+ and Ca2+ in cerebellar microsomes is mediated by an increase in the channel opening probability and not by an increase in the receptor's affinity for InsP3. A similar relationship also holds in the case of the activating effect of nucleotides.

Do transmembrane segments in proteolyzed sarcoplasmic reticulum Ca(2+)-ATPase retain their functional Ca2+ binding properties after removal of cytoplasmic fragments by proteinase K?

The present study was undertaken to investigate the Ca2+ binding properties of sarcoplasmic reticulum Ca(2+)-ATPase after removal of the cytoplasmic regions by treatment with proteinase K. One of the proteolysis cleavage sites (at the end of M6) was found unexpectedly close to the predicted membrane-water interphase, but otherwise the cleavage pattern was consistent with the presence of 10 transmembrane ATPase segments. C-terminal membranous peptides containing the putative transmembrane segments M7 to M10 accumulated after prolonged proteolysis, as well as large water-soluble fragments containing most of the phosphorylation and ATP-binding domain. Ca2+ binding was intact after cleavage of the polypeptide chain in the N-terminal region, but cuts at other locations disrupted the high affinity binding and sequential dissociation properties characteristic of native sarcoplasmic reticulum, leaving the translocation sites with only weak affinity for Ca2+. High affinity Ca2+ binding could only be maintained when proteolysis and subsequent manipulations took place in the presence of a Ca2+ concentration high enough to ensure permanent occupation of the binding sites with Ca2+. We conclude that in the absence of Ca2+, the complex of membrane-spanning segments in proteolyzed Ca(2+)-ATPase is labile, probably because of relatively free movement or rearrangement of individual segments. Our study, which is discussed in relation to results obtained on Na+,K(+)-ATPase and H+,K(+)-ATPase, emphasizes the importance of the cytosolic segments of the main polypeptide chain in exerting constraints on the intramembranous domain of a P-type ATPase.

Does a radiolabelled ligand bind to a homogeneous population of non-interacting receptor sites?

Receptor subtypes of pharmacological interest are often characterized by studies in which a particular radiolabelled ligand is competitively displaced from its binding sites, either by its unlabelled analogue (homologous displacement), or by different, unlabelled, ligands (heterologous displacement). In this article, Stéphane Swillens, Magali Waelbroeck and Philippe Champeil emphasize the fact that a single homologous displacement curve is generally unable to reveal that the radioligand binds to a heterogeneous receptor population. Overlooking this heterogeneity may, in turn, dramatically affect interpretation of heterologous displacement curves displaying more than one receptor type for the unlabelled ligand: neither the binding affinities of the ligands for the different receptors, nor the proportion of these receptors, can be estimated reliably.

Rapid kinetics of myo-inositol trisphosphate binding and dissociation in cerebellar microsomes.

Using sheep cerebellum microsomes adsorbed on a filter, we measured the kinetics of [3H]inositol 1,4,5-trisphosphate (InsP3) binding and dissociation on the subsecond time scale during rapid perfusion of the filter with [3H]InsP3-containing or InsP3-free media. At 20 degrees C and pH 7.1, in a cytosol-like medium containing MgCl2, the half-time for InsP3 dissociation was as short as 125 ms. The receptor behaved as a simple target for binding of its ligand, with the rate constant for InsP3 binding increasing linearly with InsP3 concentration. Various modulators of InsP3 binding (KCl, NaCl, pH, Mg2+, and Ca2+) were found to affect the receptor's apparent affinity for InsP3 mainly by altering the rate constant for [3H]InsP3 dissociation. ATP (but not InsP3) also accelerated [3H]InsP3 dissociation. In contrast to these modulators, luminal Ca2+ was found to have no effect on the amount of microsome-bound [3H]InsP3.