Activity-induced internalization and rapid degradation of sodium channels in cultured fetal neurons.

A regulatory mechanism for neuronal excitability consists in controlling sodium channel density at the plasma membrane. In cultured fetal neurons, activation of sodium channels by neurotoxins, e.g., veratridine and alpha-scorpion toxin (alpha-ScTx) that enhance the channel open state probability induced a rapid down-regulation of surface channels. Evidence that the initial step of activity-induced sodium channel down-regulation is mediated by internalization was provided by using 125I-alpha-ScTx as both a channel probe and activator. After its binding to surface channels, the distribution of 125I-alpha-ScTx into five subcellular compartments was quantitatively analyzed by EM autoradiography. 125I-alpha-ScTx was found to accumulate in tubulovesicular endosomes and disappear from the cell surface in a time-dependent manner. This specific distribution was prevented by addition of tetrodotoxin (TTX), a channel blocker. By using a photoreactive derivative to covalently label sodium channels at the surface of cultured neurons, we further demonstrated that they are degraded after veratridine-induced internalization. A time-dependent decrease in the amount of labeled sodium channel alpha subunit was observed after veratridine treatment. After 120 min of incubation, half of the alpha subunits were cleaved. This degradation was prevented totally by TTX addition and was accompanied by the appearance of an increasing amount of a 90-kD major proteolytic fragment that was already detected after 45-60 min of veratridine treatment. Exposure of the photoaffinity-labeled cells to amphotericin B, a sodium ionophore, gave similar results. In this case, degradation was prevented when Na+ ions were substituted by choline ions and not blocked by TTX. After veratridine- or amphotericin B-induced internalization of sodium channels, breakdown of the labeled alpha subunit was inhibited by leupeptin, while internalization was almost unaffected. Thus, cultured fetal neurons are capable of adjusting sodium channel density by an activity-dependent endocytotic process that is triggered by Na+ influx.

Voltage sensor-trapping: enhanced activation of sodium channels by beta-scorpion toxin bound to the S3-S4 loop in domain II.

Polypeptide neurotoxins alter ion channel gating by binding to extracellular receptor sites, even though the voltage sensors are in their S4 transmembrane segments. By analysis of sodium channel chimeras, a beta-scorpion toxin is shown here to negatively shift voltage dependence of activation and enhance closed state inactivation by binding to a receptor site that requires glycine 845 (Gly-845) in the S3-S4 loop at the extracellular end of the S4 segment in domain II of the alpha subunit. Toxin action requires prior depolarization to drive the S4 voltage sensors outward, but these effects are lost in the mutant G845N. The results reveal a voltage sensor-trapping model of toxin action in which the IIS4 voltage sensor is trapped in its outward, activated position by toxin binding.

Stimulation of sodium and calcium uptake by scorpion toxin in chick embryo heart cells.

Scorpion toxins, the basic miniproteins of scorpion venom, stimulated the passive uptake of Na+ and Ca2+ in chick embryo heart cells. Half-maximum stimulation was obtained for 20-30 nM Na+ and 40-50 nM Ca2+. Scorpion toxin-activated Na+ and Ca2+ uptakes were fully inhibited by tetrodotoxin, a specific inhibitor of the action potential Na+ ionophore in excitable membranes. Half-maximum inhibition was obtained with the same concentration of tetrodotoxin (10 nM) for both Na+ and Ca2+. Scorpion toxin-stimulated Ca2+ uptake was dependent on extracellular Na+ concentration and was not inhibited by Ca2+ channel blocking drugs which are inactive on heart cell action potential. Thus, in heart cells scorpion toxin affects the passive Ca2+ transport, which is coupled to passive Na+ ionphore. Other results suggest that (1) tetrodotoxin and scorpion toxin bind to different sites of the sarcolemma and (2) binding of scorpion toxin to its specific sites may unmask latent tetrodotoxin - sensitive fast channels.

Conformational variations amongst scorpion toxins.

Circular dichroism spectra were obtained for ten scorpion neurotoxins (representing five species of scorpion) in order to provide an understanding of their relative conformations in solution. Despite a high degree of amino acid sequence homology, the toxins clearly differ from each other in terms of CD-detectable structure. When superimposed, the CD spectra suggest that the toxins form a series of related conformational variants. Since the resemblances amongst the individual CD spectra can be correlated to degrees of sequence resemblance and pharmacological specificity, conformational balance could be an important factor in both toxin evolution and target recognition.

Parvalbumins from coelacanth muscle. II. Amino acid sequence of the two less acidic components.

The primary structure of the two less acidic parvalbumins (pI = 5.44 and pI = 4.95) from coelacanth muscle (Latimeria chalumnae) has been determined. They differ only by the presence or absence of a N-terminal blocking group. By the use of the automatic degradation, 69 amino acids could be placed unambiguously in the N-terminal part and 24 amino acids following the single arginine 75. Tryptic peptides were used to establish the sequence and the position of the remaining residues. The two parvalbumins examined belong to the alpha-lineage, and the rate of their molecular evolution is comparable to that found in other vertebrates.

Scorpion neurotoxin. Mode of action on neuromuscular junctions and synaptosomes.

Electrophysiological analysis of the effects of scorpion toxin I, one of the neurotoxins from the venom of the scorpion Androctonus australis Hector, upon crayfish neuromuscular junctions has shown that the toxin strongly associates with the nerve terminal to stimulate release of neurotransmitters. The biochemical approach has shown that the binding of scorpion toxin I to rat brain synaptosomes is accompanied by a decrease in their capacity to accumulate gamma-aminobutyric acid. The main effect of the toxin is to stimulate neurotransmitter release. The apparent dissociation constant of the toxin-receptor complex is 0.1-0.2 muM at 22 degrees C. The rate of dissociation is so slow that complex formation seems to be quasi-irreversible. The "quasi-irreversibility" has also been observed in electrophysiological experiments with the crayfish neuromuscular junction. Tetrodotoxin prevents scorpion toxin I action if it is incubated with synaptosomes or with crayfish neuromuscular junctions before scorpion toxin I application. Tetrodotoxin does not reverse scorpion toxin action if it is added to the preparation after scorpion toxin I. Prevention of scorpion toxin action by tetrodotoxin permits measurements of binding characteristics of this toxin to synaptosomes. The dissociation constant of the tetrodotoxin-receptor complex is 2.2 nM at 22 degrees C. No cooperativity is observed in the binding. Because of its high affinity for synaptosomes (and the "quasi-irreversibility" of the binding), scorpion toxin I appears to be a potentially excellent tool for further studies of the molecular mechanism of neurotransmitter secretion.

Isolation and characterization of colipase from porcine and human pancreatic juice by immunoaffinity chromatography.

Pure colipase was prepared by immunoaffinity chromatography from porcine and human pancreatic juice. A single form of the porcine colipase was obtained, having the structural and biological properties of previously characterized porcine procolipase A. Two forms of activated colipase (N-terminal Gly) were isolated from human pancreatic juice by the same procedure. The existence of two forms of activated colipase might arise from rapid activation of a precursor form of human colipase during collection of the pancreatic juice.

Isolation and partial structural characterization of chicken pancreatic colipase.

Colipase has been isolated from acidic extracts of chicken pancreatic tissue homogenized with Triton X-100. The cofactor fully activates bile salt inhibited mammalian lipases. The amino terminal sequence of the avian protein has been determined up to position 39 and compared to the homologous region of the mammalian colipases (pig, horse, man) previously studied. From this comparison, it appears that a high degree of homology exists between the proteins.

Neutralization of gating charges in domain II of the sodium channel alpha subunit enhances voltage-sensor trapping by a beta-scorpion toxin.

beta-Scorpion toxins shift the voltage dependence of activation of sodium channels to more negative membrane potentials, but only after a strong depolarizing prepulse to fully activate the channels. Their receptor site includes the S3-S4 loop at the extracellular end of the S4 voltage sensor in domain II of the alpha subunit. Here, we probe the role of gating charges in the IIS4 segment in beta-scorpion toxin action by mutagenesis and functional analysis of the resulting mutant sodium channels. Neutralization of the positively charged amino acid residues in the IIS4 segment by mutation to glutamine shifts the voltage dependence of channel activation to more positive membrane potentials and reduces the steepness of voltage-dependent gating, which is consistent with the presumed role of these residues as gating charges. Surprisingly, neutralization of the gating charges at the outer end of the IIS4 segment by the mutations R850Q, R850C, R853Q, and R853C markedly enhances beta-scorpion toxin action, whereas mutations R856Q, K859Q, and K862Q have no effect. In contrast to wild-type, the beta-scorpion toxin Css IV causes a negative shift of the voltage dependence of activation of mutants R853Q and R853C without a depolarizing prepulse at holding potentials from -80 to -140 mV. Reaction of mutant R853C with 2-aminoethyl methanethiosulfonate causes a positive shift of the voltage dependence of activation and restores the requirement for a depolarizing prepulse for Css IV action. Enhancement of sodium channel activation by Css IV causes large tail currents upon repolarization, indicating slowed deactivation of the IIS4 voltage sensor by the bound toxin. Our results are consistent with a voltage-sensor-trapping model in which the beta-scorpion toxin traps the IIS4 voltage sensor in its activated position as it moves outward in response to depolarization and holds it there, slowing its inward movement on deactivation and enhancing subsequent channel activation. Evidently, neutralization of R850 and R853 removes kinetic barriers to binding of the IIS4 segment by Css IV, and thereby enhances toxin-induced channel activation.

Crystallization and preliminary X-ray study of AaH IT2, and insect-specific toxin from the scorpion Androctonus australis Hector.

An insect-specific toxin from the venom of the scorpion Androctonus australis Hector has been crystallized. The crystals are orthorhombic, space groups P2(1)2(1)2(1), with cell dimensions a = 66.4 A, b = 52.5 A and c = 36.1 A. Calculations based on the unit cell volume and toxin molecular mass suggest that there are two molecules in the asymmetric unit.

Immunochemistry of scorpion alpha-toxins: study with synthetic peptides of the antigenicity of four regions of toxin II of Androctonus australis Hector.

Sequences 19-29 and 28-39 of toxin II of the North African scorpion Androctonus australis Hector have been synthesized. These two peptides correspond to the highest peaks in the hydrophilicity profile of toxin II and were thus believed to account for a significant proportion of toxin antigenicity. Affinity chromatography of solid-phase-bonded peptides allowed us to purify two sub-populations from the total IgGs raised against the native toxin. They both still bound to 125I-toxin II and showed a restricted heterogeneity in their specificity. Solid-phase immunoassays confirmed the antigenicity of these synthetic peptides and also that of two other previously described synthetic replicates of the antigenic regions of toxin II: sequences (5-14) S-S (60-64) and 50-59. The location of the four antigenic regions relative to the postulated location of the receptor-binding site of the toxin is discussed.

Epitope mapping of apamin by means of monoclonal antibodies raised against free or carrier-coupled peptide.

A panel of 20 monoclonal antibodies raised against the bee-venom peptide apamin (18 residues, 2 disulfide bridges) was prepared. Nine monoclonal antibodies (mAb) were obtained from a mouse immunized with free apamin and 11 from a mouse immunized with a mixture of free and carrier-coupled peptide. Using a panel of 11 synthetic apamin analogs, we examined the fine antigenic specificity of each antibody. The mAb generated against free apamin preferentially bound to the central part of the peptide and less frequently recognized the N- and C-terminal regions. However, monoclonal antibodies obtained by immunization with carrier-bound apamin showed a broader range of specificities, consistent with the possibility of the entire surface of this small antigen becoming immunogenic upon coupling to the carrier.

Specificity of anti-P25 antibodies produced against whole HIV-1 particles or soluble forms of the protein.

Specificity of anti-p25 antibodies produced against either whole Human Immunodeficiency Virus type 1 (HIV-1) particles in humans and chimpanzees, or against soluble forms of the protein in chimpanzees and rabbits was analyzed by ELISA using a panel of 37 long (> or = 30 residues) or shorter (9-21 residues) overlapping peptides covering the entire p25 sequence. Antibodies elicited by intact virions presented similar reactivity patterns in HIV-1-infected humans and in HIV-1-infected or immunized chimpanzees and recognized only a limited region mostly the C-terminus of the molecule. Moreover, 8 of the human sera (36%), which nonetheless reacted with high titers and avidity with native p25, did not bind to any long or short peptide. These results suggest that the majority of antibodies elicited by viral particles are presumably directed to conformational epitopes. In contrast, antibodies raised against soluble forms of p25 could react against all long peptides but one (residues 211-245) and against some short peptides, indicating that most of p25 sequence may be immunogenic under these conditions. These results suggest that the reactivity spectrum of anti p25 antibodies is rather different if they are produced against intact HIV-1 particles or the soluble protein. They also indicate that it may be possible to manipulate the specificity of the humoral immune response by using either intact virions or purified proteins.

Immunochemistry of scorpion alpha-neurotoxins. Determination of the antigenic site number and isolation of a highly enriched antibody specific to a single antigenic site of toxin II of Androctonus australis Hector.

Scorpion neurotoxins active on mammals, i.e. alpha- and beta-toxins, have been divided into several groups according to structural and also immunological criteria. A study of the alpha-toxins has been performed in order to determine the number of antigenic sites; a minimum of four Fab fragments were found to bind simultaneously to toxins I and II of Androctonus australis Hector, and toxin I of Buthus occitanus tunetanus. Taking advantage of the loss of one common antigenic site between toxin II of Androctonus australis Hector and toxin III of Buthus occitanus tunetanus, a highly purified antibody population towards a single site of toxin II of Androctonus australis Hector was isolated and characterized. This result is discussed in terms of sequence homologies between the two proteins as the amino acid sequence of toxin III of Buthus occitanus tunetanus has been determined using standard procedures: the two proteins differ at three positions, two of which (positions 10 and 64) are in the vicinity of the disulfide bridge Cys 12-Cys 63, the third (position 51) is the only one to be conservative.

Immunochemistry of scorpion alpha-toxins: purification and characterization of two functionally independent IgG populations raised against toxin II of Androctonus australis Hector.

We report the isolation and characterization of two IgG populations specific to two synthetic peptides corresponding to two antigenic sites of toxin II of the North African scorpion Androctonus australis Hector. Firstly, thanks to the use of: (1) antigenic homology studies between toxin II of A. australis Hector and toxin III of Buthus occitanus tunetanus, (2) chemical modification of toxin II of A. australis Hector, and (3) prediction of the localization of the four major antigenic sites of scorpion alpha-toxins by the method developed by Hopp and Woods [Proc. natn. Acad. Sci. U.S.A. 78, 3824-3828 (1981)], we have established that the region around the disulfide bridge between cysteines 12 and 63 as well as the stretch of residues 50-59 probably each enclosed an antigenic site. Secondly, the synthetic replicates of these regions linked to Sepharose allowed us to isolate, by immunoaffinity chromatography, two IgG populations from the whole anti-toxin II of A. australis Hector IgGs. Finally, each of these two IgG populations was shown to be specific to one antigenic site as evidenced by the multideterminant effect on the slopes of binding curves developed by Berzofsky et al. [Biochemistry 15, 2113-2121 (1976)]. Furthermore, these two IgG populations were found to be functionally independent and this could be related to the fact that the two regions carrying the two antigenic sites are not close to each other in space and that there is neither steric hindrance nor cooperative effects between them. The association constant of these site-specific IgG populations was calculated and found to be equal to 1.18-5.14 X 10(9) l/mole for IgG anti-site 1 and 1.16-5.62 X 10(9) l/mole for IgG anti-site 2 respectively by Sips [J. chem. Phys. 16, 490-495 (1948)], Scatchard [Am. N.Y. Acad. Sci. 51, 660-772 (1949)] and Steward and Petty [Immunology 23, 881-887 (1972)] representations. The index of heterogeneity of 0.9 for anti-P1 and anti-P2 indicates the purification of essentially homogeneous affinity IgG populations.

Evaluation of structure-antigenicity relationship of peptides from human immunodeficiency virus type 1 (HIV-1) p18 protein by circular dichroism.

The antigenicity of Human Immunodeficiency Virus type 1 (HIV-1) matrix p18 protein was evaluated by analyzing the specificity of anti-p18 antibodies elicited either in HIV-1 infected humans, or in HIV-1 infected or immunized chimpanzees, against a panel of long and short overlapping synthetic peptides [from 12 to 46 amino acid (aa) residues] covering the entire sequence of p18. The relationship between peptide structure and antigenicity was further investigated by probing the secondary structures of the peptides by circular dichroism. The results obtained clearly showed the immunodominance of the N-terminal region mimicked by peptide P1 (aa 2-45), which reacted with 52 and 100% of human and chimpanzee anti-p18 sera, respectively. In contrast smaller 15 aa long peptides C1, C2, C3, C4 and P3 which cover the entire sequence of immunodominant peptide P1, showed only weak or no reactivity. In contrast to widely accepted hypotheses, circular dichroism analysis of both small and large peptides secondary structures did not show any obvious correlation between antigenicity and the ability of peptides to adopt an ordered conformation.

Identification of antigenic residues on apamin recognized by polyclonal antibodies.

The structural requirements for antigenic recognition of apamin--an 18-amino acid, disulfide-bridged peptide--by rabbit antibodies were defined using a set of 18 apamin analogs in a competition liquid-phase radioimmunoassay. Some residues contribute considerably to antigenic recognition, e.g. Ala10, Arg13, and others to a lesser extent, e.g. Arg14, Glu7 and Thr8. The N- and C-terminal moieties of apamin are less antigenically important. These findings suggest that a good part of antibody specificities are directed to the central tightly folded part of the molecule. They are consistent with the observation that in saturating conditions, labeled apamin can, on average, bind one specific Fab fragment.

Use of synthetic peptides for the detection of antibodies against the nef regulating protein in sera of HIV-infected patients.

Human sera were tested for the presence of anti-nef antibodies by radioimmunoassay (RIA), with recombinant radiolabelled nef expressed in E. coli. Of the 300 HIV-positive sera tested by RIA, 70 +/- 5.3% were found to be anti-nef positive. Anti-nef antibodies bound to nef with a high affinity (K 0.5 = 2.2 x 10(-9) M). In 31 of the sera, the specificity of anti-nef antibodies was further analysed by enzyme-linked immunosorbent assay (ELISA) with large synthetic peptides ranging from 31 to 66 amino acid residues and spanning the total sequence of nef from HIV-1. The results obtained showed that the immunodominant antigenic sites of nef were located close to the N- and C-terminal regions of the molecule.

Characterization and ultrastructural localization of annexin VI from mitochondria.

Annexin VI, a member of a family of related intracellular proteins that associate reversibly with membrane phospholipids in a Ca(2+)-dependent manner, has been purified from bovine liver mitochondria and characterized. Moreover, biochemical and immunocytochemical lines of evidence are presented which strongly suggest that annexin VI is closely associated with the cristae in the inner membrane of mitochondria. These findings are consistent with a calcium channel activity of annexin VI in mitochondria.

Bot IT2: a new scorpion toxin to study receptor site on insect sodium channels.

The insect-specific Bothus occitanus tunetanus IT2 toxin is distinguishable from other scorpion toxins by its amino acid sequence and effects on sodium conductance. The present study reveals that Bot IT2 possesses in cockroach neuronal membranes a single class of high affinity (Kd = 0.3 +/- 0.1 nM) and low capacity (Bmax = 2.4 +/- 0.5 pmol/mg) binding sites. Competitive binding experiments with several known sodium channel neurotoxins reveal that the Bot IT2 binding site is in close proximity to the other toxins.