Effect of diazepam on the epileptic activity of rats with experimental photogenic epilepsy]

Chronic experiments were conducted on rats. A study was made of the effect of diazepam (in a dose of 4 mg/kg of body weight) on the specific and nonspecific mechanisms of experimentally-induced photogenic epilepsy developing as a result of tetanus toxin injection into the lateral geniculate body (LGB) and formation in this nucleus of a pathologically enhanced excitation generator (PEEG). Diazepam in the mentioned dose had a relatively weak effect on the extent of pathological enhancement of the sensory visual signal in the LGB under conditions of PEEG formation aided detection of focal interictal discharges in this nucleus, and completely inhibited generalized epileptic activity in experimental animals in the course of one hour.     

Isolated Light Chain of Tetanus Toxin Inhibits Exocytosis: Studies in Digitonin-Permeabilized Cells

Previous work indicates that the heavy chain of tetanus toxin is responsible for the binding of the toxin to the neuronal membrane and its subsequent internalization. In the present study, the light chain of tetanus toxin mimicked the holotoxin in inhibiting Ca2+-dependent secretion of [3H]norepinephrine from digitonin-permeabilized adrenal chromaffin cells. Preincubation of tetanus toxin with monoclonal antibodies to the light chain prevented the inhibition by tetanus toxin. Preincubation of tetanus toxin with nonimmune ascites fluid or with monoclonal antibodies directed against the C fragment (the C-terminal of the heavy chain) or the heavy-chain portion of the B fragment did not prevent inhibition by tetanus toxin. The data indicate that the light chain is responsible for the intracellular blockade of exocytosis.     

Tetanus toxin action: inhibition of neurotransmitter release linked to synaptobrevin proteolysis.

Tetanus toxin is a potent neurotoxin that inhibits the release of neurotransmitters from presynaptic nerve endings. The mature toxin is composed of a heavy and a light chain that are linked via a disulfide bridge. After entry of tetanus toxin into the cytoplasm, the released light chain causes block of neurotransmitter release. Recent evidence suggests that the L-chain may act as a metalloendoprotease. Here we demonstrate that blockade of neurotransmission by tetanus toxin in isolated nerve terminals is associated with a selective proteolysis of synaptobrevin, an integral membrane protein of synaptic vesicles. No other proteins appear to be affected by tetanus toxin. In addition, recombinant light chain selectively cleaves synaptobrevin when incubated with purified synaptic vesicles. Our data suggest that cleavage of synaptobrevin is the molecular mechanism of tetanus toxin action.     

Noradrenaline release from permeabilized synaptosomes is inhibited by the light chain of tetanus toxin.

Noradrenaline release from rat brain cortical synaptosomes permeabilized with streptolysin O can be triggered by microM concentrations of free Ca2+. This process was inhibited within minutes by tetanus toxin and its isolated light chain, but not by its heavy chain. The data demonstrate that the effect of tetanus toxin on NA release from purified synaptosomes is caused by the intraterminal action of its light chain.     

Characterization of tetanus toxins and toxin components by amino terminal analyses

Extract tetanus toxin, filtrate tetanus toxin, and the heavy and light chains of filtrate toxin were analyzed for their amino termini with 4-N,N-dimethylaminoazobenzene-4′isothiocyanate and phenylisothiocyanate. Extract toxin (intracellular toxin) is a single-chain polypeptide with proline as the amino terminus. Filtrate toxin (extracellular toxin) is a mixture of species produced by endogenous proteases, and showed three major amino terminal residues, proline, asparagine, and serine. Cleavage points in the filtrate toxin molecule appear to be on either side of a disulfide bond. Reductive and nonreductive preparative electrophoresis of filtrate toxin produce different species of light and heavy chains. The light chains have a single amino terminus of proline, indicating that the light chain is the amino terminal portion of the toxin molecule. The heavy chains showed no proline but rather asparagine and serine as the major amino termini. Small amounts of other amino terminal residues were present, indicating microheterogenity at the cleavage sites in the toxin. The results permit the construction of a model of tetanus toxin which is consistent with the fragments obtained from either reductive or nonreductive preparative electrophoresis of filtrate toxin.     

Structure of tetanus toxin. I. Breakdown of the toxin molecule and discrimination between polypeptide fragments.

Tetanus toxin was digested with papain, yielding one major polypeptide (Fragment C) with a molecular weight corresponding to 47,000 +/- 5%, thus comprising about one-third of the toxin molecule. Fragment C was antigenically active, atoxic, and stimulated the formation of antibodies neutralizing the lethal action of tetanus toxin in vivo. Furthermore, a second split product (Fragment B) was isolated from the papain digest, containing two polypeptide chains linked together via a disulfide bond. Fragment B (Mr = 95,000 +/- 5%) was atoxic and showed a reaction of nonidentity with Fragment C on immunodiffusion analysis against tetanus antitoxin. The basic two-chain structure (heavy and light chain polypeptide, cf. Matsuda, M., and Yoneda, M. (1975) Infect. Immun. 12, 1147-1153) of tetanus toxin has been confirmed and the relationship between Fragments B and C within this framework has been established. Fragment C was distinguished from the light chain by electrophoresis in sodium dodecyl sulfate and by immunodiffusion analysis, indicating that this fragment constitutes a portion of the heavy chain polypeptide. Fragment B showed a reaction of partial identity with the light as well as the heavy chain from tetanus toxin. Reduction of Fragment B with dithiothreitol followed by gel chromatography yielded a fraction which was indistinguishable from the light chain portion of the toxin molecule. It is concluded that Fragment B comprises the complementary portion of the heavy chain (remaining after scission of the polypeptide bond(s) releasing Fragment C) linked to the light chain by a disulfide bond.     

Tetanus toxin light chain expression in Sertoli cells of transgenic mice causes alterations of the actin cytoskeleton and disrupts spermatogenesis.

Tetanus toxin is a powerful neurotoxin known to inhibit neurotransmitter release. The tetanus toxin light chain is a metalloprotease that cleaves some members of the synaptobrevin gene family with high specificity. Here, we report the expression of a synthetic gene encoding the tetanus toxin light chain in the seminiferous epithelium of transgenic mice. Spermatogenesis was severely impaired and mature spermatozoa were completely absent. Late spermatids exhibited pleomorphic shapes and acrosomal distortions. The number of Leydig cells was greatly increased. In situ hybridization analysis revealed that the toxin acts on Sertoli cells. Affected cells exhibited an aberrant distribution of actin filaments and many cells contained large vacuoles. Our results demonstrate that tetanus toxin is active in non-neuronal cells and suggest an important function for members of the synaptobrevin gene family during the late stages of spermatogenesis.     

Tetanus toxin is a zinc protein and its inhibition of neurotransmitter release and protease activity depend on zinc.

Tetanus and botulinum neurotoxins are the most potent toxins known. They bind to nerve cells, penetrate the cytosol and block neurotransmitter release. Comparison of their predicted amino acid sequences reveals a highly conserved segment that contains the HexxH zinc binding motif of metalloendopeptidases. The metal content of tetanus toxin was then measured and it was found that one atom of zinc is bound to the light chain of tetanus toxin. Zinc could be reversibly removed by incubation with heavy metal chelators. Zn2+ is coordinated by two histidines with no involvement in cysteines, suggesting that it plays a catalytic rather than a structural role. Bound Zn2+ was found to be essential for the tetanus toxin inhibition of neurotransmitter release in Aplysia neurons injected with the light chain. The intracellular activity of the toxin was blocked by phosphoramidon, a very specific inhibitor of zinc endopeptidases. Purified preparations of light chain showed a highly specific proteolytic activity against synaptobrevin, an integral membrane protein of small synaptic vesicles. The present findings indicate that tetanus toxin, and possibly also the botulinum neurotoxins, are metalloproteases and that they block neurotransmitter release via this protease activity.     

Effect of deafferentation of the lateral geniculate body on its background activity

Elimination of reticular inputs to the lateral geniculate body (LGB) by sectioning of one half of the midbrain operculum, did not affect significantly the characteristics of the LGB evoked potential to light stimulus. At the same time LGB response to stimulation of the reticular formation by a single current impulse, though did not disappear completely, but changed greatly: its latency became twice as long, the negative component of the response was no more recorded. In conditions of LGB deafferentation, the characteristics of all rhythms of its electrical activity, besides the alpha-like one, considerably changed. At the same time, exactly this last rhythm underwent the greatest changes on the EEG of the visual cortex. On the basis of the obtained data it is suggested that the reticular formation takes a considerable and multiple part in generation of LGB rhythmic activity and that changes in its characteristics are clearly reflected in the ECoG rhythms formation. Retention of the LGB visual evoked potential and of the response to stimulation of the reticular formation after the section of one half of the midbrain operculum testifies to the presence of several reticular inputs to LGB.     

Tetanus Toxin in Dissociated Spinal Cord Cultures: Long-Term Characterization of Form and Action

The clinical course of tetanus is notable, in addition to its often dramatic clinical presentation, by the long duration of the neuromuscular symptoms. Survivors may have tetanic manifestations for several weeks after the onset of the disease. In this article we correlate the duration of specific electrophysiologic effects produced by tetanus toxin with the degradation of cell-associated toxin in primary cultures of mouse spinal cord neurons. From these studies we can conclude that the toxin has a half-life of 5-6 days. Both the heavy and the light chains of tetanus toxin degrade at similar rates. Labeled toxin, visualized by radioautography, is associated with neuronal cell bodies and neurites, and its distribution is not altered during a 1-week period following toxin exposure. Blockade of synaptic activity persists for weeks at the concentration of radiolabeled toxin used in these studies. This blockade of transmission is reversed as the toxin is degraded, suggesting that degradation of toxin may be a sufficient mechanism for recovery from tetanus.     

Structure of tetanus toxin. N-Terminal amino acid analysis of the two molecular forms of tetanus toxin and its composite chains.

N-Terminal amino acid analysis of the intracellular form of tetanus toxin revealed proline as the single terminal residue present in significant quantities. In agreement with new concepts on the structure of tetanus toxin, a second N-terminal amino acid (leucine) was exposed upon conversion to the extracellular form of the toxin molecule. These results were corroborated by analysis of the separate polypeptide chains of the extracellular toxin, and it is concluded that the light chain polypeptide constitutes the N-terminal region of the single chain toxin molecule originally synthesized by the bacterial cell. Treatment of the intracellular tetanus toxin with trypsin $\text{in vitro}$ resulted in the exposure of amino acids in addition to those found after conversion to the extracellular form effected by the bacterial protease during fermentation.     

The heavy chain of tetanus toxin can mediate the entry of cytotoxic gelonin into intact cells

An artificial conjugate of the heavy chain of tetanus toxin linked by a disulphide bond to the impermeant ribosome-inactivating protein gelonin is cytotoxic to intact HT29 cells by inhibiting intracellular protein synthesis. Neither toxin nor gelonin alone has any significant effect. This shows that the heavy chain has the ability to mediate internalization of a protein to which it is bound by a disulphide bond. Thus the normal role of the tetanus toxin heavy chain may be to allow entry of the light chain into a cell.     

条背萤成虫与幼虫发光器的超微结构观察

对水生萤火虫——条背萤Luciola substriata(Gorham)成虫和幼虫发光器的超微结构进行研究。结果表明,成虫发光器由明显的2层组成:反射层和发光层。反射层由排列紧密的“尿酸囊泡”构成,具有发达的气管结构,对光起反射作用;发光层由大量发光细胞构成,内含典型的发光颗粒、线粒体、内质网及大量糖原,该层通过发光细胞胞质内的生化反应而发光。2层均由非细胞层膜包被,间距25~30μm。发光器腹节由外向内依次为表皮、发光层、反射层和内部细胞层。幼虫发光器球形,由背射层和发光层构成,由非细胞层膜包被。背射层由单层柱状细胞构成,内含大量“尿酸囊泡”。发光层细胞膜相互绞缠,含有2种类型的发光颗粒:“致密”型和“凋亡”型,含有大量的线粒体和无定形颗粒,发光细胞之间分布着大量的气管、微气管及神经末梢,可观察到神经突触。与条背萤相比,陆生种成虫反射层和发光层均无非细胞层膜包被,2层间无明显间距,发光颗粒形状不规则,气管通常形成2分支;陆栖种幼虫发光层形状差异较大,背射层由单层或2~4层细胞构成;相似点在于,成虫发光器都由均由反射层和发光层构成,发光细胞内都含发光颗粒、线粒体及大量糖原,都具有发达的气管结构,发光颗粒相似。幼虫发光器都由背射层和发光层构成,都具有发达的气管和直接的神经支配,发光颗粒相似,都由非细胞层膜包被。     

Tetanus toxin-mediated cleavage of cellubrevin impairs exocytosis of transferrin receptor-containing vesicles in CHO cells

Cellubrevin is a member of the synaptobrevin/VAMP family of SNAREs, which has a broad tissue distribution. In fibroblastic cells it is concentrated in the vesicles which recycle transferrin receptors but its role in membrane trafficking and fusion remains to be demonstrated. Cellubrevin, like the synaptic vesicle proteins synaptobrevins I and II, can be cleaved by tetanus toxin, a metallo-endoprotease which blocks neurotransmitter release. However, nonneuronal cells are unaffected by the toxin due to lack of cell surface receptors for its heavy chain. To determine whether cellubrevin cleavage impairs exocytosis of recycling vesicles, we tested the effect of tetanus toxin light chain on the release of preinternalized transferrin from streptolysin-O-perforated CHO cells. The release was found to be temperature and ATP dependent as well as NEM sensitive. Addition of tetanus toxin light chain, but not of a proteolytically inactive form of the toxin, resulted in a partial inhibition of transferrin release which correlated with the toxin-mediated cleavage of cellubrevin. The residual release of transferrin occurring after complete cellubrevin degradation was still ATP dependent. Our results indicate that cellubrevin plays an important role in the constitutive exocytosis of vesicles which recycle plasmalemma receptors. The incomplete inhibition of transferrin release produced by the toxin suggests the existence of a cellubrevin-independent exocytotic mechanism, which may involve tetanus toxin-insensitive proteins of the synaptobrevin/VAMP family.     

The tetanus toxin light chain inhibits exocytosis

The intracellular action on exocytosis of various forms of tetanus toxin was studied using adrenal medullary chromaffin cells, the membrane barrier of which has been removed by permeabilization with streptolysin O. Such cells still release catecholamines on stimulation with calcium. The two-chain form of tetanus toxin (67 nmol/l) strongly inhibited exocytosis, but only if dithiothreitol was present as a reducing agent. Purified light chain completely prevented [3H]noradrenaline release with a half-maximal effect at about 5 nmol/l. Heavy chain (up to 11 nmol/l) and unprocessed single-chain toxin (up to 133 nmol/l) were without effect. It is concluded that the original single-chain form of tetanus toxin has to be processed by proteolysis and reduction to yield a light chain which inhibits transmitter release.     

Reductive chain separation of botulinum A toxin--a prerequisite to its inhibitory action on exocytosis in chromaffin cells

Cleavage of the disulfide bond linking the heavy and the light chains of tetanus toxin is necessary for its inhibitory action on exocytotic release of catecholamines from permeabilized chromaffin cells [(1989) FEBS Lett. 242, 245-248; (1989) J. Neurochem., in press]. The related botulinum A toxin also consists of a heavy and a light chain linked by a disulfide bond. The actions of both neurotoxins on exocytosis were presently compared using streptolysin O-permeabilized bovine adrenal chromaffin cells. Botulinum A toxin inhibited Ca2+-stimulated catecholamine release from these cells. Addition of dithiothreitol lowered the effective doses to values below 5 nM. Under the same conditions, the effective doses of tetanus toxin were decreased by a factor of five. This indicates that the interchain S-S bond of botulinum A toxin must also be split before the neurotoxin can exert its effect on exocytosis.     

Central and peripheral mechanisms in the control of the diurnal rhythm of flashing in Luciola lusitanica (Charp.)

The mechanisms underlying the diurnal rhythm of flashing in L. lusitanica were investigated. It was shown that the diurnal rhythm of flashing was present also in animals kept in continuous darkness, showing that it was not directly determined by the periodic variations of the ambient light intensity which take place through the nicthemeron. During the hours in which the animals did not flash, photogenic volleys of normal size and contour could still be recorded, although at a lower frequency; however, they were not followed by light emission. Statistical controls ruled out the possibility that the absence of flashing during daytime was due to the reduced repetition rate of the photogenic volleys. The ablation of the gonads performed during day-time was followed by the reappearence of a flash in the wake of each photogenic volley. It is concluded that two mechanism control the diurnal rhythm of flashing, namely; a central mechanism, responsible for the decrease in volley frequency; and a peripheral mechanism, of gonadal origin, which is responsible for the inhibition of the photogenic organ.     

Cloning of the structural gene for Clostridium botulinum type C1 toxin and whole nucleotide sequence of its light chain component.

The toxigenicity of Clostridium botulinum type C1 is mediated by specific bacteriophages. DNA was extracted from one of these phages. Two DNA fragments, 3 and 7.8 kb, which produced the protein reacting with antitoxin serum were cloned by using bacteriophage lambda gt11 and Escherichia coli. Both DNA fragments were then subcloned into pUC118 plasmids and transferred into E. coli cells. The nucleotide sequences of the cloned DNA fragments were analyzed by the dideoxy chain termination method, and their gene products were analyzed by Western immunoblot. The 7.8-kb fragment coded for the entire light chain component and the N terminus of the heavy chain component of the toxin, whereas the 3-kb fragment coded for the remaining heavy chain component. The entire nucleotide sequence for the light chain component was determined, and the derived amino acid sequence was compared with that of tetanus toxin. It was found that the light chain component of C1 toxin possessed several amino acid regions, in addition to the N terminus, that were homologous to tetanus toxin.     

Identification and partial characterization of a low affinity metal-binding site in the light chain of tetanus toxin.

Tetanus toxin was shown to contain a metal-binding site for zinc and copper. Equilibrium dialysis binding experiments using 65Zn indicated an association constant of 9-15 microM, with one zinc-binding site/toxin molecule. The zinc-binding site was localized to the toxin light chain as determined by binding of 65Zn to the light chain but not to the heavy chain after separation by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and transfer to Immobilon membranes. Copper was an efficient inhibitor of 65Zn binding to tetanus toxin and caused two peptide bond cleavages in the toxin light chain in the presence of ascorbate. These metal-catalyzed oxidative cleavages were inhibited by the presence of zinc. Partial characterization of metal-catalyzed oxidative modifications of a peptide based on a putative metal-binding site (HELIH) in the toxin light chain was used to map the metal-binding site in the protein.     

Cloning of the structural gene for Clostridium botulinum type C1 toxin and whole nucleotide sequence of its light chain component

The toxigenicity of Clostridium botulinum type C1 is mediated by specific bacteriophages. DNA was extracted from one of these phages. Two DNA fragments, 3 and 7.8 kb, which produced the protein reacting with antitoxin serum were cloned by using bacteriophage lambda gt11 and Escherichia coli. Both DNA fragments were then subcloned into pUC118 plasmids and transferred into E. coli cells. The nucleotide sequences of the cloned DNA fragments were analyzed by the dideoxy chain termination method, and their gene products were analyzed by Western immunoblot. The 7.8-kb fragment coded for the entire light chain component and the N terminus of the heavy chain component of the toxin, whereas the 3-kb fragment coded for the remaining heavy chain component. The entire nucleotide sequence for the light chain component was determined, and the derived amino acid sequence was compared with that of tetanus toxin. It was found that the light chain component of C1 toxin possessed several amino acid regions, in addition to the N terminus, that were homologous to tetanus toxin.