Diphtheria Toxin Forms Pores of Different Sizes Depending on Its Concentration in Membranes: Probable Relationship to Oligomerization

Diphtheria toxin forms pores in biological and model membranes upon exposure to low pH. These pores may play a critical role in the translocation of the A chain of the toxin into the cytoplasm. The effect of protein concentration on diphtheria toxin pore formation in model membrane systems was assayed by using a new fluorescence quenching method. In this method, the movement of Cascade Blue labeled dextrans of various sizes across membranes is detected by antibodies which quench Cascade Blue fluorescence. It was found that at low pH the toxin makes pores in phosphatidylcholine/phosphatidylglycerol vesicles with a size that depends on protein concentration. At the lowest toxin concentrations only the entrapped free fluorophore (MW 538) could be released from model membranes. At intermediate toxin concentrations, a 3 kD dextran could be released. At the highest toxin concentration, a 10 kD dextran could be released, but not a 70 kD dextran. Similar pore properties were found using vesicles lacking phosphatidylglycerol or containing 30% cholesterol. However, larger pores formed at lower protein concentrations in the presence of cholesterol. The dependence of pore size on toxin concentration suggests that toxin oligomerization regulates pore size. This behavior may explain some of the conflicting data on the size of the pores formed by diphtheria toxin. The formation of oligomers by membrane-inserted toxin is consistent with the results of chemical crosslinking and measurements of the self-quenching of rhodamine-labeled toxin. Based on these experiments we propose diphtheria toxin forms oligomers with a variable stoichiometry, and that pore size depends on the oligomerization state. Reasons why oligomerization could assist proper membrane insertion of the toxin and other proteins that convert from soluble to membrane-inserted states are discussed. Received: 10 March 1999/Revised: 22 June 1999     

Effects of Mutations in Proline 345 on Insertion of Diphtheria Toxin into Model Membranes

Translocation of the catalytic domain of diphtheria toxin (DT) across the endosomal membrane to the cytoplasm of mammalian cells requires the low-pH-dependent insertion of a hydrophobic helical hairpin (TH8-TH9) that is buried within the T domain of the native protein. Mutations of Pro345, which terminates helix TH8, have been reported to block toxicity for Vero cells. We found that mutant toxins in which Pro345 had been replaced by Cys, Glu, or Gly were profoundly defective at low pH in forming channels in planar phospholipid bilayers and in permeabilizing phospholipid vesicles to entrapped fluorophores. Experiments with isolated T domain containing a polarity-sensitive fluorophore attached to Cys at position 332 suggest that the P345E mutation blocks membrane insertion. None of the Pro345 mutations shifted the pH-dependence of binding in solution of the hydrophobic fluorophore, 2-p-toluidinyl-naphthalene 7-sulfonate. The results indicate that proline at position 345 is required for the T domain to insert into phospholipid bilayers or to adopt a functional conformation within the bilayer. Received: 23 July 1998/Revised: 19 October 1998     

Lysine 77 is a Key Residue in Aggregation of Equinatoxin II, a Pore-forming Toxin from Sea Anemone Actinia equina

Among eighteen point mutants of equinatoxin II produced in E. coli, containing a single cystein substitution at variable position, EqtIIK77C was chosen for its peculiar properties. It was almost 100 times less hemolytic than the wild-type, but its hemolytic activity could be restored by chemical modification of the thiol group, provided that a positive charge was reintroduced. This indicates that a positive charge at this position is necessary for toxin activity. The mutant formed larger pores as compared to the wild type, but displayed the same cation selectivity. The pores reverted to normal size upon reintroduction of the positive charge. The conformation of EqtIIK77C and its binding to lipid membranes, either vesicles or red blood cells, was almost normal. However the kinetics of calcein release from lipid vesicles was substantially slower than that of the wild-type. Taken together with the different size of the pore formed, this is an indication that mutation of Lys77 → Cys influences the normal development of the aggregate which is required for assembling the functional pore. Received: 18 May 1999/Revised: 18 September 1999     

Permeabilization of Model Lipid Membranes by Bacillus sphaericus Mosquitocidal Binary Toxin and its Individual Components

The high larvicidal effect of Bacillus sphaericus (Bs), a mosquito control agent, originates from the presence of a binary toxin (Bs Bin) composed of two proteins (BinA and BinB) that work together to lyse gut cells of susceptible larvae. We demonstrate for the first time that the binary toxin and its individual components permeabilize receptor-free large unilamellar phospholipid vesicles (LUVs) and planar lipid bilayers (PLBs) by a mechanism of pore formation. Calcein-release experiments showed that LUV permeabilization was optimally achieved at alkaline pH and in the presence of acidic lipids. BinA was more efficient than BinB, BinB facilitated the BinA effect, and their stoichiometric mixture was more effective than the full Bin toxin. In PLBs, BinA formed voltage-dependent channels of ≈100–200 pS with long open times and a high open probability. Larger channels (≥400 pS) were also observed. BinB, which inserted less easily, formed smaller channels (≤100 pS) with shorter mean open times. Channels observed after sequential addition of the two components, or formed by their 1:1 mixture (w/w), displayed BinA-like activity. Bs Bin toxin was less efficient at forming channels than the BinA/BinB mixture, with channels displaying the BinA channel behavior. Our data support the concept of BinA being principally responsible for pore formation in lipid membranes with BinB, the binding component of the toxin, playing a role in promoting channel activity. Received: 29 March 2001/Revised: 20 July 2001     

Structure-Function Relationship of the Ion Channel Formed by Diphtheria Toxin in Vero Cell Membranes

Diphtheria toxin (DT) forms cation selective channels at low pH in cell membranes and planar bilayers. The channels formed by wild-type full length toxin (DT-AB), wild-type fragment B (DT-B) and mutants of DT-B were studied in the plasma membrane of Vero cells using the patch-clamp technique. The mutations concerned certain negatively charged amino acids within the channel-forming transmembrane domain (T-domain). These residues might interact electrostatically with cations flowing through the channel, and were therefore exchanged for uncharged amino acids or lysine. The increase in whole-cell conductance induced by toxin, Δg _m , was initially determined. DT-AB induced a ∼10-fold lower Δg _m than DT-B. The mutations DT-B E327Q, DT-B D352N and DT-B E362K did not affect Δg _m , whereas DT-B D295K, DT-B D352K and DT-B D318K drastically reduced Δg _m . Single channel analysis of DT-B, DT-AB, DT-B D295K, DT-B D318K and DT-B E362K was then performed in outside-out patches. No differences were found for the single-channel conductances, but the mutants varied in their gating characteristics. DT-B D295K exhibited only a very transient channel activity. DT-AB as well as DT-B D318K displayed significantly lower open probability and mean dwell times than DT-B. Hence, the lower channel forming efficiency of DT-AB and DT-B D318K as compared to DT-B is reflected on the molecular level by their tendency to spend more time in the closed position and the fast flickering mode. Altogether, the present work shows that replacements of single amino acids distributed throughout a large part of the transmembrane domain (T-domain) strongly affect the overall channel activity expressed as Δg _m and the gating kinetics of single channels. This indicates clearly that the channel activity observed in DT-exposed Vero cells at low pH is inherent to DT itself and not due to DT-activation of an endogenous channel. Received: 20 June 1996/Revised: 8 November 1996     

Structural Evidence for the Evolution of Pyrogenic Toxin Superantigens

Cells from metazoan organisms are eliminated in a variety of physiological and pathophysiological processes by apoptosis. In this report, we describe the cloning and characterization of molecules from the marine sponges Geodia cydonium and Suberites domuncula, whose domains show a high similarity to those that are found in molecules of the vertebrate Bcl-2 superfamily and of the death receptors. The Bcl-2 proteins contain up to four Bcl-2 homology regions (BH). Two Bcl-2-related molecules have been identified from sponges that are provided with two of those regions, BH1 and BH2, and are termed Bcl-2 homology proteins (BHP). The G. cydonium molecule, BHP1_GC, has a putative size of 28,164, while the related sequence from S. domuncula, BHP1_SD, has a M _r of 24,187. Phylogenetic analyses of the entire two sponge BHPs revealed a high similarity to members of the mammalian Bcl-2 superfamilies and to the Caenorhabditis elegans Ced-9. When the two domains, BH1 and BH2, are analyzed separately, again the highest similarity was found to the members of the Bcl-2 superfamily, but a clearly lower relationship to the C. elegans BH1 and BH2 domains in Ced-9. In unrooted phylogenetic trees the sponge BH1 and BH2 are grouped among the mammalian sequences and are only distantly related to the C. elegans BH domains. The analysis of the gene structure of the G. cydonium BHP showed that the single intron present is located within the BH2 domain at the same position as in C. elegans and rat Bcl-x_L. In addition, a sponge molecule comprising two death domains has been characterized from G. cydonium. The two death domains of the potential proapoptotic molecule GC_DD2, M _r 24,970, share a high similarity with the Fas-FADD/MORT1 domains. A death domain-containing molecule has not been identified in the C. elegans genome. The phylogenetic analysis revealed that the sponge domain originated from an ankyrin building block from which the mammalian Fas-FADD/MORT1 evolved. It is suggested that the apoptotic pathways that involve members of the Bcl-2 superfamily and of the death receptors are already present in the lowest metazoan phylum, the Porifera. Received: 27 July 1999 / Accepted: 28 December 1999     

Activity of Diphtheria Toxin II. Early Events in the Intoxication of HeLa Cells

The initial steps in the interaction of diphtheria toxin with HeLa cells were studied. It was demonstrated that lethal doses of toxin are rapidly adsorbed to the cell. The kinetics of uptake, as measured by lethality, indicated that a single toxin molecule is able to cause cell death. Studies on the effect of pH on intoxication showed that adsorption of toxin occurred over a wide pH range but was partially inhibited at high pH values. Experiments to determine the influence of the ionic environment on intoxication indicated that adsorption of toxin did not take place in the absence of salts and was partially inhibited in the presence of a polyanion. The evidence indicates that the initial binding of toxin to the cell is electrostatic in nature, involving positively charged surface groups. Attempts to demonstrate specific receptors for the attachment of toxin to cells were unsuccessful, suggesting that toxin adsorption may be a nonspecific process. The effect of energy inhibitors on intoxication was examined. Sodium fluoride, an inhibitor of glycolysis, almost completely prevented intoxication in HeLa cells, whereas inhibitors of respiration and oxidative phosphorylation had no effect. Sodium fluoride did not prevent adsorption of toxin but appeared to inhibit a later step in the intoxication process, perhaps the transport of toxin to subsurface or intracellular levels.     

Block of Voltage-dependent Calcium Channel by the Green Mamba Toxin Calcicludine

A number of peptide toxins derived from marine snails and various spiders have been shown to potently inhibit voltage-dependent calcium channels. Here, we describe the effect of calcicludine, a 60 amino-acid peptide isolated from the venom of the green mamba (Dendroaspis angusticeps), on transiently expressed high voltage-activated calcium channels. Upon application of calcicludine, L-type (α_{1 C} ) calcium channels underwent a rapid, irreversible decrease in peak current amplitude with no change in current kinetics, or any apparent voltage-dependence. However, even at saturating toxin concentrations, block was always incomplete with a maximum inhibition of 58%, indicating either partial pore block, or an effect on channel gating. Block nonetheless was of high affinity with an IC₅₀ value of 88 nm. Three other types of high voltage activated channels tested (α_{1 A} , α_{1 B} , and α_{1 E} ) exhibited a diametrically different response to calcicludine. First, the maximal inhibition observed was around 10%, furthermore, the voltage-dependence of channel activation was shifted slightly towards more negative potentials. Thus, at relatively hyperpolarized test potentials, calcicludine actually upregulated current activity of (N-type) α_{1 B} channels by as much as 50%. Finally, the use of several chimeric channels combining the major transmembrane domains of α_{1 C} and α_{1 E} revealed that calcicludine block of L-type calcium channels involves interactions with multiple structural domains. Overall, calcicludine is a potent and selective inhibitor of neuronal L-type channels with a unique mode of action. Received: 22 September 1999/Revised: 1 December 1999     

Lipid-induced Pore Formation of the Bacillus thuringiensis Cry1Aa Insecticidal Toxin

After activation, Bacillus thuringiensis (Bt) insecticidal toxin forms pores in larval midgut epithelial cell membranes, leading to host death. Although the crystal structure of the soluble form of Cry1Aa has been determined, the conformation of the pores and the mechanism of toxin interaction with and insertion into membranes are still not clear. Here we show that Cry1Aa spontaneously inserts into lipid mono- and bilayer membranes of appropriate compositions. Fourier Transform InfraRed spectroscopy (FTIR) indicates that insertion is accompanied by conformational changes characterized mainly by an unfolding of the β-sheet domains. Moreover, Atomic Force Microscopy (AFM) imaging strongly suggests that the pores are composed of four subunits surrounding a 1.5 nm diameter central depression. Received: 14 July 2000/Revised: 28 December 2000     

Influence of Membrane Physical State on the Lysosomal Proton Permeability

Influence of membrane physical state on the proton permeability of isolated lysosomes was assessed by measuring the membrane potential with 3,3′-dipropylthiadicarbocyanine iodide and monitoring their proton leakage with p-nitrophenol. Changes in the membrane order were examined by the steady-state fluorescence anisotropy of 1,6-diphenyl-1,3,5-hexatriene. Both the membrane potential and proton leakage increased with fluidizing the lysosomal membranes by benzyl alcohol and decreased with rigidifying the membranes by cholesteryl hemisuccinate. The proton permeability increased to the maximum of 42% by the benzyl alcohol treatment and decreased to the minimum of 38.1% by the cholesteryl hemisuccinate treatment. Treating the lysosomes with protonophore CCCP increased the proton permeability by 58%. The effects of the membrane fluidization and rigidification can be reversed by rigidifying the fluidized membranes and fluidizing the rigidified membranes, respectively. The results indicate that the proton permeability of lysosomes increased and decreased with increasing and decreasing their membrane fluidity, respectively. Moreover, the lysosomal proton permeability did not alter further if the changes, either an increase or a decrease, in the fluidity exceeded some amount. The results suggest that the proton permeability of lysosomes can be modulated finitely by the alterations in their membrane physical state. Received: 27 September 1999 / Revised: 27 December 1999     

Influence of Cys-130 S. aureus Alpha-toxin on Planar Lipid Bilayer and Erythrocyte Membranes

Replacement of an amino acid residue at position 130 -Gly by Cys- in the primary structure of Staphylococcus aureus alpha-toxin decreases the single-channel conductance induced by the toxin in planar lipid bilayers. Concomitantly, the pH value at which the channel becomes unable to discriminate between Cl⁻ and K⁺ ions is also decreased. By contrast, the pH dependence of the efficiency of the mutant toxin to form ion channels in lipid bilayers was unchanged (maximum efficiency at pH 5.5–6.0). The asymmetry and nonlinearity of the current-voltage characteristics of the channel were increased by the point mutation but the diameter of the water pore induced by the mutant toxin, evaluated in lipid bilayers and in erythrocyte membranes, was found to be indistinguishable from that formed by wild-type toxin and equal to 2.4–2.6 nm. Alterations at the ``trans mouth' were found to be responsible for all observed changes of the channel properties. This mouth is situated close to the surface of the second leaflet of a bilayer lipid membrane. The data obtained allows us to propose that the region around residue 130 in fact determines the main features of the ST-channel and takes part in the formation of the trans entrance of the channel. Received: 8 September 1995/Revised: 20 November 1996     

Ion Channels Induced in Planar Lipid Bilayers by the Bacillus thuringiensis Toxin Cry1Aa in the Presence of Gypsy Moth (Lymantria dispar) Brush Border Membrane

The apical brush border membrane, the main target site of Bacillus thuringiensis toxins, was isolated from gypsy moth (Lymantria dispar) larval midguts and fused to artificial planar lipid bilayer membranes. Under asymmetrical N-methyl-d-glucamine-HCl conditions (450 mm cis/150 mm trans, pH 9.0), which significantly reduce endogenous channel activity, trypsin-activated Cry1Aa, a B. thuringiensis insecticidal protein active against the gypsy moth in vivo, induced a large increase in bilayer membrane conductance at much lower concentrations (1.1–2.15 nm) than in receptor-free bilayer membranes. At least 5 main single-channel transitions with conductances ranging from 85 to 420 pS were resolved. These Cry1Aa channels share similar ionic selectivity with P _Cl/P _NMDG permeability ratios ranging from 4 to 8. They show no evidence of current rectification. Analysis of the macroscopic current flowing through the composite bilayer suggested voltage-dependence of several channels. In comparison, the conductance of the pores formed by 100–500 nm Cry1Aa in receptor-free bilayer membranes was significantly smaller (about 8-fold) and their P _Cl/P _NMDG permeability ratios were also reduced (2- to 4-fold). This study provides a detailed demonstration that the target insect midgut brush border membrane material promotes considerably pore formation by a B. thuringiensis Cry toxin and that this interaction results in altered channel properties. Received: 23 February 2001/Revised: 15 June 2001     

Permeability Increase Induced by Escherichia coli Hemolysin A in Human Macrophages is Due to the Formation of Ionic Pores: A Patch Clamp Characterization

Escherichia coli hemolysin is known to cause hemolysis of red blood cells by forming hydrophilic pores in their cell membrane. Hemolysin-induced pores have been directly visualized in model systems such as planar lipid membranes and unilamellar vesicles. However this hemolysin, like all the members of a related family of toxins called Repeat Toxins, is a potent leukotoxin. To investigate whether the formation of channels is involved also in its leukotoxic activity, we used patch-clamped human macrophages as targets. Indeed, when exposed to the hemolysin, these cells developed additional pores into their membrane. Such exogenous pores had properties very different from the endogenous channels already present in the cell membrane (primarily K⁺ channels), but very similar to the pores formed by the toxin in purely lipidic model membranes. Observed properties were: large single channel conductance, cation over anion selectivity but weak discrimination among different cations, quasilinear current-voltage characteristic and the existence of a flickering pre-open state of small conductance. The selectivity properties of the toxin channels appearing in phospholipid vesicles were also investigated, using a specially adapted polarization/depolarization assay, and were found to be completely consistent with that of the current fluctuations observed in excised macrophage patches. Received: 14 August 1995/Revised: 2 October 1995     

Protease Inhibitors Fail To Prevent Pore Formation by the Activated Bacillus thuringiensis Toxin Cry1Aa in Insect Brush Border Membrane Vesicles

To investigate whether membrane proteases are involved in the activity of Bacillus thuringiensis insecticidal toxins, the rate of pore formation by trypsin-activated Cry1Aa was monitored in the presence of a variety of protease inhibitors with Manduca sexta midgut brush border membrane vesicles and by a light-scattering assay. Most of the inhibitors tested had no effect on the pore-forming ability of the toxin. However, phenylmethylsulfonyl fluoride, a serine protease inhibitor, promoted pore formation, although this stimulation only occurred at higher inhibitor concentrations than those commonly used to inhibit proteases. Among the metalloprotease inhibitors, o-phenanthroline had no significant effect; EDTA and EGTA reduced the rate of pore formation at pH 10.5, but only EDTA was inhibitory at pH 7.5. Neither chelator affected the properties of the pores already formed after incubation of the vesicles with the toxin. Taken together, these results indicate that, once activated, Cry1Aa is completely functional and does not require further proteolysis. The effect of EDTA and EGTA is probably better explained by their ability to chelate divalent cations that could be necessary for the stability of the toxin's receptors or involved elsewhere in the mechanism of pore formation.     

The Diphtheria Toxin Channel-forming T Domain Translocates Its Own NH2-Terminal Region Across Planar Bilayers

The T domain of diphtheria toxin, which extends from residue 202 to 378, causes the translocation of the catalytic A fragment (residues 1–201) across endosomal membranes and also forms ion-conducting channels in planar phospholipid bilayers. The carboxy terminal 57-amino acid segment (322–378) in the T domain is all that is required to form these channels, but its ability to do so is greatly augmented by the portion of the T domain upstream from this. In this work, we show that in association with channel formation by the T domain, its NH₂ terminus, as well as some or all of the adjacent hydrophilic 63 amino acid segment, cross the lipid bilayer. The phenomenon that enabled us to demonstrate that the NH₂-terminal region of the T domain was translocated across the membrane was the rapid closure of channels at cis negative voltages when the T domain contained a histidine tag at its NH₂ terminus. The inhibition of this effect by trans nickel, and by trans streptavidin when the histidine tag sequence was biotinylated, clearly established that the histidine tag was present on the trans side of the membrane. Furthermore, the inhibition of rapid channel closure by trans trypsin, combined with mutagenesis to localize the trypsin site, indicated that some portion of the 63 amino acid NH₂-terminal segment of the T domain was also translocated to the trans side of the membrane. If the NH₂ terminus was forced to remain on the cis side, by streptavidin binding to the biotinylated histidine tag sequence, channel formation was severely disrupted. Thus, normal channel formation by the T domain requires that its NH₂ terminus be translocated across the membrane from the cis to the trans side, even though the NH₂ terminus is >100 residues removed from the channel-forming part of the molecule.     

Cation Permeability and Selectivity of a Root Plasma Membrane Calcium Channel

Calcium channels in the plasma membrane of root cells fulfill both nutritional and signaling roles. The permeability of these channels to different cations determines the magnitude of their cation conductances, their effects on cell membrane potential and their contribution to cation toxicities. The selectivity of the rca channel, a Ca²⁺-permeable channel from the plasma membrane of wheat (Triticum aestivum L.) roots, was studied following its incorporation into planar lipid bilayers. The permeation of K⁺, Na⁺, Ca²⁺ and Mg²⁺ through the pore of the rca channel was modeled. It was assumed that cations permeated in single file through a pore with three energy barriers and two ion-binding sites. Differences in permeation between divalent and monovalent cations were attributed largely to the affinity of the ion binding sites. The model suggested that significant negative surface charge was present in the vestibules to the pore and that the pore could accommodate two cations simultaneously, which repelled each other strongly. The pore structure of the rca channel appeared to differ from that of L-type calcium channels from animal cell membranes since its ion binding sites had a lower affinity for divalent cations. The model adequately accounted for the diverse permeation phenomena observed for the rca channel. It described the apparent submillimolar K _m for the relationship between unitary conductance and Ca²⁺ activity, the differences in selectivity sequences obtained from measurements of conductance and permeability ratios, the changes in relative cation permeabilities with solution ionic composition, and the complex effects of Ca²⁺ on K⁺ and Na⁺ currents through the channel. Having established the adequacy of the model, it was used to predict the unitary currents that would be observed under the ionic conditions employed in patch-clamp experiments and to demonstrate the high selectivity of the rca channel for Ca²⁺ influx under physiological conditions. Received: 23 August 1999/Revised: 12 November 1999     

Heart and T-Lymphocyte Cell Surfaces Both Exhibit Positive Cooperativity in Binding a Membrane-Lytic Toxin

Cobra venom cytotoxins (CTX) have been shown to disrupt cells as different as immunocytes, skeletal myocytes, erythrocytes and tumor cells. Nevertheless, even subpopulations of tumor cells are differentially susceptible to CTX by an order of magnitude. In the present study, our objective was to compare CTX-specific binding with cytolytic potency for two disparate cell types in vitro. We investigated the lytic activity of cytotoxin-III from Naja naja atra (NNA, fraction D) using heart cells and human leukemic T-cells (CEM cells). For both cell types, 50% cytolysis, assessed by tetrazolium dye conversion, occurred with μm concentrations of toxin (EC₅₀= 2.2 μm). We examined the binding of radiolabeled CTX III to both heart cells and CEM cells and found the apparent dissociation constant (K _Dapp) to be 0.69 μm and 0.75 μm, for CEM and heart cells respectively. The B _max for the CEM cells was 1.0 fmoles/cell and that for heart cells was 5.2 fmoles/cell, both exhibiting positive cooperativity between the sites (Hill coefficients 1.4, T-cells; 1.6, heart). Relatively modest dissociation constants plus high numbers of binding sites per cell are consistent with a model of CTX binding to plasma membranes by interaction with phospholipids in the bilayer. Our results suggest that the lytic activity of this cytotoxin follows its binding to a population of sites on the cells in a cooperative fashion. Received: 8 May 1995/Revised: 17 November 1995     

The Molecular Evolutionary History of a Winged Bean α-Chymotrypsin Inhibitor and Modeling of Its Mutations Through Structural Analyses

A serine protease inhibitor of the Kunitz-STI (soybean trypsin inhibitor) family, isolated from the legume seeds of winged bean, was found to inhibit chymotrypsin at a 1:2 stoichiometric ratio. When the structure was determined in our laboratory, it was found to form a characteristic β-trefoil fold, which is also seen in other proteins from distant families and sources. The folding organization divides the protein into three approximately equal subdomains related by a pseudo-threefold axis of symmetry passing parallel to the barrel axis of the trefoil. Following the now established idea that the present-day genes originated from ancestral minigenes through evolution, the origin of the proteins having this β-trefoil organization is scrutinized using its subdomain motif as the search probe. The results, based mainly on structural analyses, indicate the independent existence of such a motif, mimicking the unknown ancestral protein(s) that might have been distributed in nature, not only by gene duplication, but also by insertion and permutation in other folds. The understanding led to a hypothesis for the possible origin of the Kunitz-STI family. On the basis of this model of evolution, structurally hypervariable regions were located on the protein where mutations could be designed and a broad range of engineering of the protein's activity could be conceived. Received: 20 January 1999 / Accepted: 6 October 1999     

Rectification of the Olfactory Cyclic Nucleotide-Gated Channel by Intracellular Polyamines

Polyamine-induced inward rectification of cyclic nucleotide-gated channels was studied in inside-out patches from rat olfactory neurons. The polyamines, spermine, spermidine and putrescine, induced an `instantaneous' voltage-dependent inhibition with K <sub>d</sub> values at 0 mV of 39, 121 μm and 2.7 mm, respectively. Hill coefficients for inhibition were significantly < 1, suggesting an allosteric inhibitory mechanism. The Woodhull model for voltage-dependent block predicted that all 3 polyamines bound to a site 1/3 of the electrical distance through the membrane from the internal side. Instantaneous inhibition was relieved at positive potentials, implying significant polyamine permeation. Spermine also induced exponential current relaxations to a `steady-state' impermeant level. This inhibition was also mediated by a binding site 1/3 of the electrical distance through the pore, but with a K _d of 2.6 mm. Spermine inhibition was explained by postulating two spermine binding sites at a similar depth. Occupation of the first site occurs rapidly and with high affinity, but once a spermine molecule has bound, it inhibits spermine occupation of the second binding site via electrostatic repulsion. This repulsion is overcome at higher membrane potentials, but results in a lower apparent binding affinity for the second spermine molecule. The on-rate constant for the second spermine binding saturated at a low rate (∼200 sec⁻¹ at +120 mV), providing further evidence for an allosteric mechanism. Polyamine-induced inward rectification was significant at physiological concentrations. Received: 17 February 1999/Revised: 27 April 1999     

1-Anilino-8-Naphtalene Sulfonate Probes a Gastric HK-ATPase Potassium Site Whose Access Requires Ionophores

1-anilino-8-naphtalenesulfonate (ANS) is a hydrophobic dipole previously used to demonstrate that the proton for potassium exchange by the gastric HK-ATPase is electroneutral. In this paper, we demonstrate that ANS binds to gastric membranes and probes conformational changes of the HK-ATPase independently of any active H for K exchange. Conformational changes require the presence of potassium-valinomycin and are not triggered by sodium. Potassium effect is enhanced by ATP, in the presence and in the absence of magnesium and, by ADP, in the presence of magnesium. Labeling of the pig HK-ATPase K518 by fluorescein-5-isothiocyanate inhibits the enzyme activity and knocks out the ATP effect on ANS fluorescence. Scherring 28080 and the monoclonal antibody 95-111, two competitive inhibitors of K-activated ATPase dephosphorylation, do not modify K-effect on ANS fluorescence but inhibit ATP effects. This supports that ANS does not probe K-site between the H1–H2 loop. Treatment of gastric membranes with trypsin does not inhibit the ANS response to potassium but does inhibit the response to ATP. This suggests that the ATP site inducing the ANS response is cytoplasmic and the potassium site is intramembranous. Titration reveals that one mole of ANS interacts with one mole of ATPase. We suggest that ANS probes a hydrophobic potassium site of gastric ATPase and that addition of ATP and ADP-Mg embed that site. Received: 16 July 1997/Revised: 10 June 1998