Binding of scorpion and sea anemone neurotoxins to a common site related to the action potential Na+ ionophore in neuroblastoma cells.

The protein neurotoxin II from the venom of the scorpion $\text{Androctonus}\text{australis}$ Hector was labeled with ¹²⁵I by the lactoperoxidase method to a specific radioactivity of about 100 μCi/μg without loss of biological activity. The labeled neurotoxin binds specifically to a single class of non intereacting binding sites of high affinity (K_D = 0.3 – 0.6 nM) and low capacity (4000 – 8000 sites/cell) to electrically excitable neuroblastoma cells. Relation of these sites to the action potential Na⁺ channel is derived from identical concentration dependence of scorpion toxin binding and increase in duration and amplitude of action potential. The protein neurotoxin II from the sea anemone $\text{Anemona sulcata}$ also affects the closing of the action potential Na⁺ ionophore in nerve axons. The unlabelled sea anemone toxin modifies ¹²⁵I-labeled scorpion toxin II binding to neuroblastoma cells by increasing the apparent K_D for labeled scorpion toxin without modification of the number of binding sites. It is concluded that both $\text{Androctonus}$ scorpion toxin II and $\text{Anemona}$ sea anemone toxin II interact competitively with a regulatory component of the action potential Na⁺ channel.     

alpha-Galactoside Binding Proteins from Plant Membranes: Isolation, Characterization, and Relation to Helminthosporoside Binding Proteins of Sugarcane

α-Galactoside binding proteins were isolated from cellular membranes of mint and tobacco as well as two clones of sugarcane which differ in their sensitivity to helminthosporoside, a toxic galactoside. Sodium trichloroacetate was used to disrupt membranes after which the proteins were purified using a melibiose-Sepharose-6B affinity column. Proteins from mint, tobacco, and susceptible sugarcane had equal electrophoretic mobilities, whereas resistant sugarcane protein migrated more slowly. Pretreatment of the proteins with fluorescamine caused them to migrate with the tracking dye. Each of the proteins had molecular weights of about 100,000 and each was shown to be oligomeric. Gel filtration revealed that aqueous solutions of these membrane proteins contained a mixture of size species which included a high molecular weight multimer and lower molecular weight oligomers. The relative abundance of the oligomers was dependent upon protein concentration: the lower concentrations yielded higher relative amounts of oligomers (Kenfield and Strobel 1980 Biochim Biophys Acta 600: 705-712). Also, the binding activity of these receptors was inversely proportional to protein concentration. At low protein concentration (4 micrograms per milliliter), the K_d's of each of the proteins for galactinol, raffinose, and helminthosporoside was about 10 micromolar. At high protein concentrations (100 micrograms per milliliter), mint and resistant sugarcane proteins failed to bind α-galactosyl ligands, whereas proteins from tobacco and susceptible sugarcane exhibited a markedly decreased binding activity compared to that at lower protein concentrations. Binding proteins from susceptible sugarcane were mixed with receptors from either resistant sugarcane or mint at low protein concentrations, then assayed for binding activity. Such mixtures showed a concentration-dependent decrease in binding activity analogous to the activity of homogeneous protein solutions. Bovine serum albumin, a nonsubunit protein, had no effect on the binding activity of the protein from susceptible sugarcane. Thus, receptors from diverse plants can associate in vitro and form functional oligomers. The amino acid composition of each of the binding proteins was similar but not identical. The significance of these results is discussed in regard to regulation of carbohydrate transport and sensitivity to phytotoxins.     

Eyespot Disease of Sugarcane : INDUCTION OF HOST-SPECIFIC TOXIN AND ITS INTERACTION WITH LEAF CELLS

Helminthosporium sacchari produces a toxin which is responsible for the symptoms of eyespot disease in Saccharum officinarum. A rapid and highly repeatable bioassay based on increase in conductivity of tissue leachates showed that the interaction of toxin with sugarcane obeys Michaelis-Menten hyperbolic saturation kinetics. There was no evidence for positive or negative cooperation interaction. Resistant and susceptible cultivars of sugar cane had distinctive conductivity characteristics. Co-cultures of H. sacchari and suspension cultures of sugarcane gave up to a 4,000-fold increase in toxin production.     

Saturable binding to cell membranes of the presynanptic neurotoxin, β-Bungarotoxin

Brief exposure to the protein neurotoxin, β-bungarotoxin, is known to disrupt neuromuscular transmission irreversibly by blocking the release of transmitter from the nerve terminal. This neurotoxin also has a phospholipase A2 activity, although phospholipases in general are not very toxic. To determine if the toxicity of this molecule might result from specific binding to neural tissue, we have looked for high affinity, saturable binding using ¹²⁵I-labeled toxin. At low membrane protein concentration ¹²⁵I-labeled toxin binding was directly proportional to the amount of membrane; at fixed membrane concentration ¹²⁵I-labeled toxin showed saturable binding. It was unlikely that iodination markedly changed the toxin's properties since the iodinated toxin had a comparable binding affinity to that of native toxin as judged by competition experiments. Comparison of toxin binding to brain, liver and red blood cell membranes showed that all had high affinity binding sites with dissociation constants between one and two nanomolar. This is comparable to the concentrations previously shown to inhibit mitochondrial function. However, the density of these sites showed marked variation such that the density of sites was 13.0 pmol/mg protein for a brain membrane preparation, 2.4 pmol/mg for liver and 0.25 pmol/mg for red blood cell membranes.In earlier work we had shown that calcium uptake by brain mitochondria is inhibited at much lower toxin concentrations than is liver mitochondrial uptake. Both liver and brain mitochondria bind toxin specifically, but the density of ¹²⁵I-labeled toxin binding sites on brain mitochondrial prepartions ($\text{3.3 ± 0.3}\text{pmol/mg}$) exceeded by a factor of ten the density on liver mitochondrial preparations ($\text{0.3 ± 0.05}\text{pmol/mg}$). It is also shown that the labeled toxin does not cross synaptosomal membranes, suggesting that mitochondria may not be the site of action of the toxin in vivo. We conclude the β-bungarotoxin is an enzyme which can bind specifically with high affinity to cell membranes.     

Structure and action of heteronemertine polypeptide toxins Binding of cerebratulus lacteus toxin B-IV to axon membrane vesicles

The binding of the crustacean selective protein neurotoxin, toxin B-IV, from the nemertine Cerebratulus lacteus to lobster axonal vesicles has been studied. A highly radioactive, pharmacologically active derivative of toxin B-IV has been prepared by reaction with Bolton-Hunter reagent. Saturation binding and competition of ¹²⁵I-labeled toxin B-IV by native toxin B-IV have shown specific binding of ¹²⁵I-labeled toxin B-IV to a single class of binding sites with a dissociation constant of 5–20 nM and a binding site capacity, corrected for vesicle sidedness, of 6–9 pmol per mg membrane protein. This compares to a value of 3.8 pmol [³H]saxitoxin bound per mg in the same tissue. Analysis of the kinetics of toxin B-IV association ($\text{k}{}_{\mathrm{+1}}\text{=7.3·10}{}^5\text{M}{}^{\mathrm{?1}}\text{·s}{}^{\mathrm{?1}}$) and dissociation ($\text{k}{}_{\mathrm{?\; 1}}\text{=2·10}{}^{\mathrm{?3}}\text{s}{}^{\mathrm{?1}}$) shows a nearly identical $\text{K}{}_{\mathrm{<mtext>d</mtext>}}$ of about 3 nM. There is no competition of toxin B-IV binding by purified toxin from Leiurus quinquestriatus venom while Centruroides sculpturatus Ewing toxin I appears to cause a small enhancement of toxin B-IV binding.     

Serinol phosphate as an intermediate in serinol formation in sugarcane

A novel compound, serinol phosphate, was identified in sugarcane (Saccharum officinarum) clone 51NG97. It was produced by an enzyme-mediated transamination of dihydroxyacetone phosphate with either alanine, glutamate, aspartate, or glutamine serving equally well as an amino donor. Some detectable phosphatase activity was present in crude leaf enzyme preparation that hydrolyzed serinol phosphate. A proposal for a pathway of the biosynthesis of serinol in sugarcane was formulated.

Serinol can serve as an “activator” of toxin production in attenuated cultures of the sugarcane pathogen Helminthosporium sacchari and it is present in susceptible clone 51NG97. Resistant clone H50-7209 does not possess serinol and likewise no dihydroxyacetone phosphate transaminase activity could be demonstrated in enzyme preparations of this clone. The concept of toxin activation in attenuated fungus cultures is briefly discussed relative to disease resistance and susceptibility.

     

Specific binding and pharmacological interactions of apamin,the neurotoxin from bee venom,with guinea pig colon

This paper describes the interaction of apamin, the bee venom neurotoxin, with its receptor in the guinea pig colon. The pharmacological activity of the toxin was assayed by measuring its contracting effect on guinea pig colon preparations that had been previously relaxed by neurotensin. The IC₅₀ value of apamin in this $\text{in vitro}$ bioassay is 7 nM. These pharmacological data are compared to the binding properties of apamin to smooth muscle membranes prepared from guinea pig colon. The highly radiolabeled monoiododerivative of apamin binds to its colon receptor with a dissociation constant $\text{K}{}_{\mathrm{<mtext>d</mtext>}}{}^1\text{= 36}\text{pM}$. The maximal binding capacity of colonic membranes is 30^dfmol/mg of protein. The dissociation constant of the unmodified toxin is 23 pM. The difference between the toxin concentrations that produce half-maximal effects in the binding and pharmacological studies arises from the different experimental conditions used for the two assays.     

Glycoprotein characteristics of the sodium channel saxitoxin-binding component from mammalian sarcolemma

The saxitoxin-binding component of the excitable membrane sodium channel exhibits glycoprotein characteristics as evidenced by its specific interaction with various agarose-immobilized lectins. The detergent-solubilized saxitoxin-binding component interacts quantitatively with immobilized wheat germ agglutinin and concanavalin A and fractionally with immobilized Lens culinaris hemagglutinin and Ricinus communis agglutinin. These lectins preferentially bind $\text{N-}\text{acetylglucosamine}$ and sialic acid (wheat germ agglutinin), mannose (concanavalin A and Lens cunilaris and galactose (Ricinus communis). Removal of terminal sialic acid residues by neuraminidase markedly decreases binding to immobilized wheat germ agglutinin but uncovers sites capable of interacting with lectins specific for galactose and $\text{N-}\text{acetylgalactosamine}$. $\text{β-N-}\text{acetylglucosaminidase}$, an exoglycosidase has no effect on the binding of the channel protein to wheat germ agglutinin. Similarly, phospholipase C has no effect on binding of the solubilized toxin binding component to this lectin. Neither wheat germ agglutinin nor concanavalin A free in solution alters the number of toxin binding sites or their affinity for toxin. The sodium channel saxitoxin-binding component appears to be a glycoprotein containing terminal sialic acid residues and internal mannose, galactose, $\text{N-}\text{acetylglucosamine}$, and $\text{N-}\text{acetylgalactosamine}$ residues. The toxin binding site is spatially separated from the binding sites for the lectins studied. The effect of these sugar moieties must be considered when evaluating the biophysical parameters of the sodium channel.     

Synthesis of diphtheria toxin in E. coli cell-free lysate

An $\text{E. coli}$ cell-free lysate was used to translate $\text{C. diphtheriae}$ RNA from nontoxinogenic C₇(?), C₇ infected with β tox⁺ corynebacteriophage, and $\text{C. diphtheriae}$ strain PW8. De novo synthesis of toxin was detected by immune precipitation with antitoxin, ADP-ribosylation of mammalian elongation factor 2 and rabbit skin test. The results indicated that toxin is produced in the $\text{E. coli}$ protein synthesizing system primed with RNA from cells infected with tox⁺ bacteriophage and is absent in systems primed with RNA from C₇(?) cells.     

The relationship between membrane ATPase activity in sugarcane and heat-induced resistance to helminthosporoside.

1. Heating of susceptible sugarcane leaves (4 h at 35 degrees C) renders them resistant, for 24 h, to the effects of helminthosporoside. Membrane ATPase activity is reduced by 50% as a result of the heat treatment. When the leaves again become susceptible (after 24 h), membrane. ATPase activity is fully restored. 2. Inhibitors of membrane ATPase activity protect susceptible leaves from the effects of helminthosporoside (KF, EDTA, and octylguanidine). 3. Helminthosporoside activates (30%) membrane ATPase in microsomes from susceptible, but not heat-treated (resistant) leaves. Once heat-treated leaves again become susceptible, helminthosporoside activation of membrane ATPase activity resumes. 4. A plot of the production of helminthosporoside-induced symptoms, and membrane ATPase activity as a function of the reciprocal of the absolute temperature reveals that both have sharp breaks at 32 degrees C. 5. Protoplasts of susceptible cane are rendered insensitivity to the effects of the toxin in a medium deficient in K+ and Mg2+. When these ions are added, cell sensitivity to the toxin is restored. Since K+ uptake in plants is mediated by membrane ATPase, a connection with this enzyme activity can be made to cell sensitivity to the toxin.     

Interconversions of aglycone and host-selective toxin from Helminthosporium sacchari

Helminthosporium sacchari, a fungus that causes disease in sugarcane, produces oligosaccharide-sesquiterpene toxins (HS toxins A, B, and C) that are required for infection and disease development. Two free sesquiterpenes were isolated from mycelium but not from culture fluids of the fungus. One sesquiterpene was identified by HPLC and mass spectrometry as an aglycone of HS toxin C and could be obtained by enzymatic hydrolysis of this toxin. The other sesquiterpene appeared to be the 2-keto form of the first compound. The aglycone from toxin C hydrolysis was labelled with tritium by successive treatments with active manganese dioxide, sodium boro[³H]hydride, and lithium aluminium hydride. The labelled compound was fed to cultures of H. sacchari, radioactivity was incorporated into HS toxin C and into lower molecular weight homologues. The results suggest a metabolic route (aglycone → metabolite Y, → HS toxin → metabolite X) for the biosynthesis of HS toxin; metabolites X and Y are lower molecular weight homologues of the toxin.     

Calcium-independent and dependent steps in action of Clostridium perfringens enterotoxin on HeLa and Vero cells.

Purified enterotoxin (20–200 ng/ml) of $\text{Clostridium}$$\text{perfringens}$ rapidly induced bled and balloon formation on HeLa and Vero cells in the presence, but not the absence, of Ca²⁺. The action of the toxin involved two, sequential, temperature-dependent steps: The first was Ca²⁺-independent and included binding of toxin and the bound toxin after 30–60 sec could no longer be removed by washing. The second step was Ca²⁺-dependent and eventually led to bled and balloon formation. On adding Ca²⁺ to cells pretreated with toxin in Ca²⁺-free medium, bled and balloon formation started immediately. The ionophore A23187 mimicked the action of toxin. The effects of sucrose (0.2 M), trypsin-treatment of the cells and various pretreatments of the toxin on the action of enterotoxin were studied.     

Solubilization and partial characterization of the tetrodotoxin binding component from nerve axons

The tetrodotoxin binding component from garfish olfactory nerve membranes has been solubilized using the nonionic detergent Triton X-100. Tetrodotoxin binds to the solubilized component with a dissociation constant K_D = 2.5 × 10^?9$\text{M}$ and under saturating conditions 1.95 × 10^?12 moles of tetrodotoxin are bound per milligram of solubilized protein. Upon solubilization the toxin binding component becomes much less stable towards heat, chemical modification and enzymatic degradation. Sucrose gradient velocity sedimentation yields an S value of 9.2 for the extracted binding component and from gel filtration data the binding component appears to be slightly larger than β-D-galactosidase.     

Effects of cholera toxin on cellular and paracellular sodium fluxes in rabbit ileum

The diarrhea observed in patients which cholera is known to be related to secretion of water and electrolytes into the intestinal lumen. However, the exact mechanisms involved in these secretory processes have remained unclear. Although it is clear that purified toxin acts on epithelial cell metabolism, its activity on Na⁺ transport across intestinal mucosa is equivocal: reported either to prevent net Na⁺ absorption or to cause net secretion of Na⁺ from serosa to mucosa. Since total transmural Na⁺ fluxes across “leaky” epithelia involve very significant movement via a paracellular shunt pathway, we studied the effects of cholera toxin on the cellular and paracellular pathways of Na⁺ movement. Unidirectional Na⁺ fluxes were examined as functions of applied potential in control tissues and in tissues from the same animal treated with purified cholera toxin. Treatment of rabbit ileum in vitro with toxin stimulated the cellular component of serosa-to-mucosa Na⁺ flux (from $\text{2.41 ± 0.49 μ}\text{equiv./h}$ per cm² under control conditions to $\text{4.71 ± 0.43 μ}\text{equiv./h}$ per cm² after treatment with toxin, $\text{P < 0.01}$). The effect of cholera toxin on Na⁺ movement through the cells from mucosa to serosa appeared to be insignificant. Finally, a marked decrease in the Na⁺ permeability ($\text{P < 0.01}$) and no detectable significant changes in transference number for Na⁺ of the paracellular shunt pathway were observed following treatment with cholera toxin. These results provide direct evidence for the hypothesis that purified cholera toxin stimulates active sodium secretion but has minimal effect on sodium absorption.     

Bromoacetylcholine as an affinity label of the acetylcholine receptor from Torpedo californica

Bromoacetyl[methyl-³H]choline is a highly specific label for the reduced acetylcholine binding site on the acetylcholine receptor from $\text{Torpedo californica}$. Only one of two binding sites per receptor monomer is susceptible to labeling. The labeled site is on the α chain of the receptor.     

Lectin and cholera toxin binding to guinea pig tumor (104C1) cell surfaces before and after glycosphingolipid incorporation

¹²⁵I-Labeled $\text{Dolichos biflorus}$ lectin and cholera toxin were used as probes for identification of Forssman- and GM1-type receptor sites on guinea pig tumor (104C1) cell surfaces. Increased binding of ¹²⁵I-labeled lectin and toxin to 104C1 cell surfaces was observed after the cells were treated with exogenous Forssman glycosphingolipid and GM1 ganglioside, respectively. Biosynthesis $\text{in vitro}$ of these two glycosphingolipids from their precursor molecules was established using a membrane preparation isolated from confluent cultures of guinea pig tumor 104C1 cells.     

The identification of an invertebrate acetylcholine receptor

The results of a series of experimental studies have culminated in the identification of an acetylcholine receptor from the invertebrate $\text{Limulus polyphemus}$. The binding ligand α-bungarotoxin was used to identify a specific protein in the central nervous system tissue of this organism. The specific interaction of α-bungarotoxin with an acetylcholine receptor has been confirmed by physiological, competitive binding, subcellular fractionation and autoradiographic techniques. The toxin binding protein was solubilized and exhibited properties consistent with the nature of a nicotinic cholinergic receptor. Therefore, the identified protein is proposed as an acetylcholine receptor protein from the central nervous system of this invertebrate species.     

Inhibition of anion transport in human red blood cells by 5,5′-dithiobis(2-nitrobenzoic acid)

The uptake of [³²P]phosphate into human red blood cells was inhibited ($\text{K}{}_{\mathrm{<mtext>i</mtext>}}\text{= 0.6}\text{mM}$) by the sulfhydryl reagent 5,5′-dithiobis(2-nitrobenzoic acid) (DTNB). 2-Nitro-5-thiobenzoic acid (NTB), the reduced form of DTNB, was a less potent inhibitor ($\text{K}{}_{\mathrm{<mtext>i</mtext>}}\text{= 7}\text{mM}$). The inhibition of anion transport by DTNB could be reversed by washing DTNB-treated cells with isotonic buffer, or by incubating DTNB-treated cells with 2-mercaptoethanol, which converted DTNB to NTB. DTNB competitively inhibited the binding of 4-[¹⁴C]-benzamido-4′-aminostilbene-2,2′-disulfonate, a potent inhibitor of anion transport ($\text{K}{}_{\mathrm{<mtext>i</mtext>}}\text{= 1?2 μ}\text{M}$), to band 3 protein in cells and ghost membranes. These results suggest that the stilbene-disulfonate binding site in band 3 protein can readily accommodate the organic anion DTNB, and that inhibition by DTNB was not due to reaction with an essential sulfhydryl group.     

Effect of the Specific Toxin in Helminthosporium victoriae on Host Cell Membranes

Helminthosporium victoriae toxin, which affects only hosts of the toxin-producing fungus, causes loss of electrolytes from roots, leaves, and coleoptiles of treated plants. Root hair cells lost the ability to plasmolyze after 20 minutes exposure to toxin in solution; comparable resistant cells retained plasmolytic ability during 3 hours exposure. Toxin stopped uptake of exogenous amino acids and Pi by susceptible but not by resistant tissue. Incorporation of ³²P into organic-P and ¹⁴C-amino acids into protein was blocked in susceptible but not in resistant tissue. Apparent free space increased in susceptible but not in resistant roots. The increase was evident within 30 minutes, and reached 80% free space after 2 hours exposure to toxin. When cell wall-free protoplasts were exposed to 0.16 μg toxin/ml, protoplasmic streaming stopped and all plasma membranes of susceptible protoplasts broke within 1 hour. Resistant protoplasts were not affected significantly. Data support the hypothesis of a primary lesion of toxin in the plasma membrane. Effects on synthesis could result from lack of transport of exogenous solutes to sites of synthesis. It is possible that all other observed effects of toxin are secondary to membrane damage.